Research Projects
Innovative Solar Absorbers for Renewable and Sustainable Energy (i-SOLARSE)
01-09-2024 / 31-12-2027
Research Head: Juan Carlos Sánchez López / Ramón Escobar Galindo
Financial Source: Ministerio de Ciencia e Innovación y Universidades
Code: PID2023-147102NB-I00 (Proyectos de Generación de Conocimiento)
Research Team: Cristina T. Rojas Ruiz, Bertrand Lacroix (Universidad de Sevilla), María Sonia Mato Rodríguez (Universidad Complutense de Madrid)
In recent years, the search for new materials with improved performance for use in renewables energies has become a crucial issue due to the depletion of fossil fuels, increasing concentration of greenhouse gases and climate changes. Among them, solar energy stands out as one of the best choices due to its cleanliness and inexhaustibility, offering the potential to generate both heat and electricity. The current research project is oriented towards the development of advanced solar selective absorber materials, specifically designed to meet the required operating conditions in terms of temperature and environment for solar-thermal applications.
For this purpose, solar selective absorder structures based on transition metal oxides and oxynitrides will be grown on metallic substrates (stainless steel 316L and Inconel 625) using magnetron sputtering technology (including the high-power impulse variant – HiPIMS). In particular, CrAlSiON-based multilayered coatings will be essayed for operating conditions typical of concentrating solar power plants: T≥650 ºC in air (solar tower receivers) and T≤500 ºC in vacuum (parabolic trough collectors). Intrinsic black non-stoichiometric Al, Cr and Ti oxides will be explored for solar-thermal applications at 200ºC (air or vacuum) to produce heat usable in industry and household applications. A complementary approach will consist of the development of thin barrier layers to block the ion interdiffusion from the substrate to the solar absorber systems and the generation of black oxides by direct oxidation of the substrates in controlled environment. Basic aspects to be considered are the solar conversion performance, thermal stability, oxidation resistance and aging behavior.
The project will comprise all stages, starting from the synthesis of the individual material components for the solar selective structures, followed by the design and simulation of the optical behavior, and ending by the growth of the full solar selective absorber structure. The structural and chemical characterization, the evaluation of the thermal stability and oxidation resistance will run simultaneously with the aim of optimizing the solar absorber selective coatings with the best performance and durability. The final phase will involve validation in conditions closely resembling the intended application, encompassing both laboratory and field tests.
Photonic Design of Optoelectronic Devices based on Perovskite Quantum Dot Solids (PQD-Photonics)
01-09-2024 / 31-12-2027
Research Head: Hernán Ruy Míguez García / Mauricio Calvo Roggiani
Financial Source: Ministerio de Ciencia e Innovación y Universidades
Code: PID2023-149344OB-I00 (Proyectos de Generación del Conocimiento)
Research Team: Juan Galisteo López, Laura Caliò, Carmen Gutiérrez Lázaro, Lucía Castillo Flores
Quantum dot (QD) solids are mainly prepared by deposition of nanocrystal suspensions onto flat substrates, typically after a lengthy ligand exchange procedure, needed to achieve the dot-to-dot charge transport required in an optoelectronic device. While this process has been optimized to yield high absorption coefficient and luminescence quantum yield together with good carrier mobility, which has allowed the fabrication of efficient solar cells and light emitting diodes, QD films built in this way usually present imperfections (inhomogeneities, aggregates, thickness variations, surface roughness…), whose main fingerprint is the presence of diffuse light scattering that gives rise to partial opacity. One of the deleterious consequences of this scattering is that it hinders the implementation of a photonic design that could maximize light absorption and/or emission through a rational, deterministic, spatial distribution of the in-coupled or out-coupled electromagnetic fields. Recent advances made by the applicant group in (i) the development of transparent (i.e., scattering free) lead halide perovskite quantum dot (PQD) based solids, (ii) the realization of the first optoelectronic materials based on these transparent PQD solids and (iii) the analysis of charge transport through them by advanced spectroscopic techniques, allow foreseeing a credible solution to this limitation. In this context, the PQD-Photonics project aims at realizing improved configurations in which both the optical and charge transport properties are optimized, giving rise to more energy efficient, versatile, stable and functional PQD solid-based optoelectronic devices. Enhanced performance of solar cells, color converting layers, light emitting diodes, lasers, and photodetectors, is targeted by integrating a variety of device processing-compatible photonic designs. Although all materials and devices that will be studied are halide perovskite based, the results of this project could be straightforwardly extended to any kind of solution processed semiconductor QD, which widely broadens the range of materials and devices that can benefit from the results achieved in the PQD-Photonics project.
Production of hydrogen and tunable syn-gas from ethanolic fermentation streams and biochars (HySynChar)
01-09-2024 / 30-11-2027
Research Head: Miguel Angel Centeno Gallego / María Isabel Domínguez Leal
Financial Source: Ministerio de Ciencia e Innovación y Universidades
Code: PID2023-147861OB-C22 (Proyectos de Generación de Conocimiento)
Research Team: Leidy Marcela Martínez Tejada
This project is part of the coordinated project HySynChar, which aims to develop a novel strategy for the integration of a set of reactions and processes, based on catalytic and gasification technologies, for the production of energy vectors and products of high added value (hydrogen and oxygenated compounds, particularly acetaldehyde, formic acid and acetic acid) and synthesis gas of adjustable composition. This process will allow the valorisation of both the main output streams of the ethanolic fermentation process of sugars, bioethanol and carbon dioxide, as well as residual biochars, thereby contributing to the development of sustainable energy technologies. The main objective of the ICMS project is to generate hydrogen streams from formic acid produced by selective oxidation of acetaldehyde, obtained by subproject 1 (INMA) from bioethanol. Specifically, the ICMS project focuses on the study of the reactions of i) selective oxidation of acetaldehyde, both in liquid and gas phase, for the production of formic and/or acetic acid and ii) dehydrogenation of formic acid. For this purpose, it is intended to develop novel, active, selective and stable catalysts, preferably based on transition metals, for both reactions. In the case of the selective oxidation of acetaldehyde, catalysts based on VOx supported on TiO2 or SiO2, FeOx supported on CeO2-ZrO2 and Au supported on TiO2, SiO2 and CeO2-ZrO2 will be studied, aiming to control the selectivity of the reaction towards the production of formic or acetic acid. In the case of the formic acid dehydrogenation reaction, the catalysts will be based on Cu or Fe and the objective is to achieve continuous production of stable, CO-free hydrogen streams from dilute formic acid streams using low-cost, environmentally friendly catalysts.
All prepared materials will be fully characterised structurally and chemically by a wide variety of techniques (XRD, XPS, SEM, HRTEM, Raman, DRIFTS, TPR/TPD, UV-Vis, Textural Analysis, etc.), both pre- and post-reaction, in order to evaluate the possible modifications occurred during the reaction. Likewise, studies will be carried out under reaction conditions (in-situ and operating) by IR/DRIFTS spectroscopy coupled with MS, which, together with the activity and characterisation results, will allow the analysis of the mechanism of the reactions and thus be able to establish the structure-activity relationship in each case. Knowledge of this relationship will allow the optimisation of the designed catalyst. The solids with the best catalytic results in all reactions studied by the consortium INMA-ICMS will be structured in monolithic reactors to analyse the effect of the reactor configuration.
Advancing supercapacitors with plasma-designed multifunctional hybrid materials
28-06-2024 / 28-06-2027
Research Head: Juan Ramón Sánchez Valencia
Financial Source: Ministerio de Ciencia, Innovación y Universidades "Proyectos de Colaboración Internacional"
Code: PCI2024-153451 Programa Internacional: M-ERA Net COFUND
Research Team: Ángel Barranco Quero, Ana Isabel Borrás Martos, Vanda Fortio Godinho, Victor Joaquín Rico Gavira, Jorge Gil Rostra, Francisco Javier Aparicio Rebollo, Juan Pedro Espinós Manzorro
Current rechargeable energy storage devices face important drawbacks, including long-term raw materials availability, life-cycle, high prices, and safety issues. Due to their fast discharge capabilities and long-term life cycle, supercapacitors are potential candidates for future energy storage. However, supercapacitors must overcome technical problems with designing electrodes and electrolytes, stability, energy density, and attaining industry standards.
ANGSTROM proposes an environmentally friendly plasma-enabled approach for developing advanced materials for supercapacitors, comprising vertical nanocarbon and highly porous active materials, the latter consisting of covalent organic frameworks or a new type of “a la carte” conformal porous metal oxides. The multidisciplinary and ambitious methodology and unique expertise will make it possible to surpass the state-of-the-art supercapacitors with superior capacitive storage, high energy density, and potential for reusability.
The ANGSTROM consortium includes three international academic and one industrial partner. The Spanish National Research Council (CSIC), Spain, coordinates the consortium. The other academic partners are the Jožef Stefan Institute (JSI), Slovenia, and The Central European Institute of Technology (CEITEC), and the industrial company is IQS nano, these two latter from Czechia.Programa Internacional: M-ERA Net COFUND
Flexible and advanced Biofuel technology through an innovative microwave pYrolysis & hydrogen-free hydrodeoxygenation process: FLEXBY
01-05-2024 / 30-04-2028
Research Head: Tomás Ramírez Reina
Financial Source: Unión Europea
Code: GRANT AGREEMENT NO. 101144144 (HORIZON EUROPE)
Research Team: José Antonio Odriozola Gordón, Laura Pastor Pérez, Luis F. Bobadilla
Biomass-derived liquid transportation fuels have been proposed as part of the solution to mitigate climate change and many countries are providing incentives to support the growth of bioenergy utilization. Nevertheless, most biofuels currently are made from food-related sources and have a negative impact on food production. The development of cost-effective solutions to minimize carbon waste and inhibit biogenic effluent gas emissions in sustainable biofuel production processes is still at an early stage of development.
FLEXBY intends to go significantly boost this development by producing advanced biofuel through an innovative, cost-efficient process that will reach TRL5. At FLEXBY we will produce biofuel using biogenic waste from microalgae cultivated in domestic wastewater as well as the oily sludge from refineries. This residual biomass will undergo a microwave pyrolysis treatment to produce three different fractions: bio-liquid, pyro-gas, and bio-char. The bio-liquid fraction will be converted to jet, diesel, and marine bio-fuels (heavy transport biofuels) through a versatile and innovative Hydrogen-free Hydrodeoxygenation. The gaseous fraction will be converted to bio-hydrogen through a steam-reforming water gas-shift process (WGS) and preferential CO oxidation (PrOx). Both liquid and gaseous biofuel will be tested and validated in fuel cells to produce electricity, along with an evaluation of their respective suitability for the transport sector. FLEXBY promotes a circular economy by recycling biomass residues and all sub-products obtained during the project. The combined expertise of the industrially-driven consortium (formed by 1 LE, 4 SMEs, 2 universities, 1 non-profit association, and 2 RTOs) from 5 different countries will be able to achieve these objectives. In terms of impact, FLEXBY will increase the use of advanced biofuels in the heavy transport sector, mitigating climate impact in key areas of the global economy
X-ray Detectors Based on Perovskite Composites
01-10-2023 / 31-03-2025
Research Head: Miguel Anaya Martín
Financial Source: BBVA
Code: LEO23-11319
Photon counting detectors have the potential to transform how we obtain CT scans to achieve low dose, high resolution images for medical diagnosis and monitoring. However, the materials currently used to manufacture these detectors require extremely high purity and are, therefore, economically expensive to achieve, limiting their widespread adoption. This project will employ perovskite composites to considerably reduce production costs and facilitate the scalability of direct X-ray detectors, thus opening avenues to making them universal in CT imaging.
Photonic materials boost afterglow in transparent persistent luminescence thin films
01-12-2023 / 30-11-2025
Research Head: Gabriel S. Lozano Barbero
Financial Source: Ministerio de Ciencia e Innovación. "Europa Excelencia"
Code: EUR2023-143467
Persistent luminescent (PersL) materials are able to store optical energy in structural defects that act as traps and generate light long after the excitation source disappears, i.e. afterglow, allowing the introduction of time as a design element in new lighting solutions. Despite the advantages associated with size reduction, the properties of persistent nanomaterials are far from those of their bulk counterparts. PHLOW seeks to find new ways to control PersL by designing the optical environment of emitters, a path unexplored until today. To this end, it is proposed to process transparent thin films with PersL for integration into photonic architectures in order to optimize the charging process and improve the amount of light emitted during the afterglow. It is relevant to note that the charge storage and emission processes compete with each other. That is, as the traps are filled, they are also partially emptied in a dynamic process. However, there is no strategy specifically designed to alter the charging process or increase the population of the traps. At the same time, the radiative de-excitation rate of a transition depends on the optical environment through the local density of optical states. For this reason, the optical design is expected to have an impact, in addition to the outcoupling mechanism, on the intrinsic process of light generation, which should allow altering the trap population balance, affecting the charge kinetics and the intensity of the PersL. Thus, the general objective is to study the impact of changes in the optical environment on the processes of energy storage and persistent light emission in order to highlight the potential of optical design as a tool to control PersL in transparent thin films. This naturally interdisciplinary approach will have a profound scientific impact, as photonics has never been explored to control the charge and emission mechanisms that determine PersL, but also technological, as it enables the development of timedependent light sources to drive more versatile color converters, smart labels, novel coatings for anti-counterfeiting or optical data storage.
Design and 3D printing of personalized porous biphasic implants for the treatment of osteochondral defects
01-09-2023 / 31-08-2026
Research Head: Dr. Yadir Torres Hernández (US) y Dra. Ana Alcudia Cruz (US)
Financial Source: Ministerio de Ciencia e Innovación
Code: PID2022-137911OB-I00
Research Team: Dr. Francisco José Gotor Martínez, Dr. Manuel de Miguel Rodríguez (US), Dra. Ana Isabel Raya Bermúdez (Universidad de Córdoba), Dr. Juan Morgaz Rodríguez (Universidad de Córdoba), Dra. María José Montoya García (US), Dr. Eugenio Velasco Ortega (US), Dra. Mercedes Giner García (US), Dra. Loreto Monsalve Guil (US), Dra. Belén Begines Ruiz (US), Dr. Francisco José García García (US)
Currently, the number of musculoskeletal injuries that require the replacement of both bone and cartilage tissue is drastically increasing. These conditions, referred as to osteochondral defects (OCD), are derived from different diseases. The Lancet Commission estimated that, in 2020, more than 500 million people were affected only by osteoarthritis, with an associated medical cost between 1% and 2.5% of the gross domestic product in high-income countries. Most treatments applied for OCD just address the cartilage tissue, so the use of biphasic implants to simultaneously treat both tissues is under investigation nowadays. These implants are formed by a rigid section that substitutes the subchondral bone tissue and a soft section that mimics que cartilage. In this project, the novel fabrication of bespoke biphasic implants is proposed for the OCD treatment in articular regions. The use of Direct Ink Writing (DIW) 3D printing for both tissues will allow a complete implant personalization. On the one hand, DIW will be optimized for the 3D printing of a β-Ti alloy to obtain a 3D part with an improved biomechanical and biofunctional balance, according to the previous experience of our group in the fabrication of Tibased implants by different methodologies. This technology allows control of the objects porosity whose optimization, together with the use of β-Ti alloy, will lead to a bone substitute with a Youngs modulus very close to the host bone tissue, reducing the stress-shielding problem without compromising mechanical performance. The DIW printer used will include two reservoirs, to simultaneously print two different inks, and a rotary axis for the printing on top of the implants curved surface. In addition, the inclusion of a chitosan-based composite containing bioglasses in the metallic section will enhance the osseointegration and will reduce the bacterial proliferation due to the antimicrobial activity of the polymer. The most promising printed parts will be evaluated in vitro, using hOB, and in vivo in New Zealand White Rabbits. The results obtained with the printed β-Ti alloy will be compared with the results obtained from commercially pure Ti and different Ti alloys substrates previously prepared by the research group using the space-holder technique to select the bone substitute with the best performance. On the other hand, a novel Interpenetrated Polymer Network (IPN) will be optimized to generate a hydrogel with the required properties to be printed and perform as the cartilage tissue. This IPN will contain 2 different polymeric materials. The main one will be based on polymers with previously demonstrated antibiofouling capacity, in which some researchers of the team have experience, and a home-synthetized crosslinker based on hydrophilic carbohydrates to improve biocompatibility. The second polymer will be hyaluronic acid crosslinked with a sugar-derived hydrophilic diamine to enhance the chondrocytes adhesion and proliferation. The proportion of each
component and the porosity obtained with the printing strategy will be evaluated to maintain the antibiofouling behavior but offering the required performance in terms of viscoelasticity and wear resistance to mimic the cartilage. In addition, their cell and gene behavior will be evaluated in vitro. Finally, the final biphasic implant will be fabricated using the most promising tissue substitutes and tested in vivo in New Zealand White Rabbits.
Design of Advanced ceramics with 2D nanomaterials for High-temperature ElectrochemicAl Devices
01-09-2023 / 31-08-2027
Research Head: Ana Morales Rodríguez / Rosalía Poyato Galán
Financial Source: Ministerio de Ciencia e Innovación
Code: PID2022-140191NB-I00
Research Team: Ángela Gallardo López, Felipe Gutiérrez Mora, Rocío del Carmen Moriche Tirado
The advance in knowledge in ceramic matrix composites with 2D nanomaterial fillers is essential to address their future use in technological applications such as high-temperature electrochemical devices. Thus, a deep understanding of the basis of their new functionalities and optimized performance is needed.
This proposal outlines a systematic study of composites with 8 mol% yttria-stabilized zirconia matrix, a well-known ionic conductor, incorporating two different 2D laminar nanomaterials -graphene or boron nitride nanosheets- as fillers, intended for use in solid oxide fuel cells, with the aim to deepen in the understanding of the mechanisms that control their thermal, mechanical and electrical behavior.
To begin with, a processing study will be carried out in order to obtain composites with an optimized microstructure, always pursuing a homogeneous distribution of the 2D nanomaterial throughout the ceramic matrix and a high density. In a first step, the powder processing routine will be optimized in order to enhance the dispersion of the 2D nanostructure in the composite powder. In a second step, a sintering study with different temperatures and pressures will be carried out with the aim of obtaining fully- dense composites. The effect of the 2D nanostructure incorporation on the ceramic composite microstructure will be analyzed in terms of the crystalline phases and distribution, size and structural integrity of the 2D nanomaterials.
Thermal diffusivity and conductivity measurements will be conducted on the sintered composites, as a function of temperature and under different atmospheres to analyze heat dissipation and the effect of the filler dispersion and orientation in the thermal response. These thermal properties are essential since operation of the solid oxide fuel cell takes place at high temperature.
To ensure structural stability of the composites during operation, high-temperature deformation tests will be performed controlling stress, temperature, and working atmosphere conditions. The identification of the microscopic mechanisms responsible of the creep behavior as well as the comprehension of the fracture mechanisms and plasticity of the composites will be pursued to allow for prediction and control of their structural response in service.
The electrical conductivity measurements fundamental for this application will be carried out on the composites as a function of temperature in order to assess the effect of the incorporation of the different 2D nanostructures. The conduction type -ionic, mixed or electronic- for the composites with different graphene nanosheets contents will be identified.
Innovative techniques based on electric fields for the preparation of all solid state batteries
01-09-2023 / 31-08-2026
Research Head: Eva Gil González
Financial Source: Ministerio de Ciencia e Innovación
Code: PID2022-141199OA-I00 (Proyectos Investigación Orientada)
Research Team: Xin Li, Sandra Molina Molina, Ahmed Taibi
The development of energy storage technologies is essential for the transition to a climate-neutral economy. All-Solid-State Batteries (ASSBs) are promising candidates to solve the functional problems of convectional lithium-ion batteries that are currently dominating the technological market. ASSBs replace the flammable organic liquid electrolyte of traditional devices with a non-flammable solid, which improves the safety of this devices, among many other advantages. Thus, solid electrolytes have experienced great development in the last decades, where oxide and phosphate-types solid electrolytes are emerging as a very important group due to their high ionic conductivities, wide electrochemical window, and good compatibility with lithium metal. However, the high temperatures (for long periods of time) required for their synthesis and processing consume a large amount of energy, which considerably limit their economic competitiveness and also deteriorate their physical properties due to lithium volatilization. Furthermore, the co-sintering process with the other active materials of the cells (anode and cathode) is extremely complicated, as the high temperatures promote the appearance of secondary phases and high interfacial resistances that, unfortunately, limit the lifespan of ASSBs. This is precisely one of the major challenges facing the development of these devices. INNOBEC proposes an innovative approach to address the aforementioned problem by implementing the Flash Sintering (FS) to ASSBs. FS consists in simultaneously applying an electric field and heat to a ceramic sample, so that the densification of the material is achieved almost instantaneously and at much lower temperatures than those used in conventional methodologies. FS not only reduces the energy cost, but also enables the processing of materials with limited thermal stability, such as solid electrolytes. Additionally, since FS are considered as "non-equilibrium" techniques, some materials have been granted with exceptional properties, such as suplerplasticity in ceramics and improved ionic conductivities, which has been attributed to the generation of a large number of defects. Furthermore, FS is a highly versatile technique and, very recently, it has been demonstrated the Reaction Flash Sintering (RFS), where not only the sintering but also the chemical reaction are merged in a single step, boosting the efficiency of the process and amplifying the possibilities offered by FS.
INNOBEC aims to take advantages of the competitiveness offered by FS and RFS of reduced processing times and temperatures to prepare materials with optimized properties for ASSBs, specifically, oxide-types and phosphate-type ceramic solid electrolytes as well as ceramic composites with mixed ionic-electronic conduction to be used as cathodes or anodes. The ultimate goal of INNOBEC is the co-sintering in a single step of ASSB-type multilayer structures and the evaluation of their electrochemical performance. INNOBEC is an innovative project, which merges the previous experience of the PI in both fields ASSBs and FS, proposing a new energy efficient methodology to facilitate the preparation and processing of solid electrolytes so that the serious interfacial problems, arising from the co-sintering and that are slowing down the development of ASSBs, can be alleviated.
Ligand Free Halide Perovskites in Porous GaN for Next Generation Light Emission Applications (PEROGAN)
01-09-2023 / 31-08-2026
Research Head: Miguel Anaya Martín / Sol Carretero Palacios
Financial Source: Ministerio de Ciencia e Innovación
Code: PID2022-142525OA-I00
Research Team: Alberto Jiménez Solano
PEROGAN proposes a material disruption by growing halide perovskite emitters within nanostructured GaN pores. The project will be driven by the optical modelling and visualisation of the material properties where the interplay between photophysics, composition and structure will be controlled at the nanoscale. Defect tolerant, soft perovskite materials will be combined with highly performing GaN in a monolithic fashion. This project will lay the foundations for future scientific achievements where operating, cost-effective LEDs with output a la carte will be able to cover photonic applications such as lighting, imaging and sensing.
Materials for High performance thermal energy storage system based on hybrid molten salts and carbonates
01-09-2023 / 31-08-2026
Research Head: Luis Allan Pérez Maqueda / Antonio Perejón Pazo
Financial Source: Ministerio de Ciencia e Innovación
Code: PID2022-140815OB-C22
Research Team: Pedro Enrique Sánchez Jiménez, José Manuel Valverde Millán (US)
The main objective of the HIPERTES project is the development of a new concept of high-temperature thermochemical energy storage based on a hybrid system of carbonates and molten salts in a single reactor. Subproject 2 focuses mainly on aspects related to the development of materials suitable for these new operating conditions, as well as their optimization and the study of the behavior of the materials during thermochemical cycles.
Although there are proposals based on the use of solid additives to try to improve the cyclability and performance of thermochemical processes based on carbonation/calcination reactions, these solutions have a limit, since a decay of the activity is always observed with the number of cycles, which becomes more evident as the number of cycles increases. In this project, a novel solution based on hybrid systems of carbonates with molten salts is proposed. The salts will provide an increase in the reactivity of both calcination and carbonation, especially improving the kinetics of the diffusive processes.
Thus, the salts are expected to provide (i) fast calcination and carbonation kinetics to make the loading and unloading processes as fast as possible and (ii) high multicyclic stability avoiding deactivation processes by sintering and pore blocking. Two types of systems are proposed, one based on porous pellets that would be impregnated with the salts and the other based on molten salt baths where the carbonate particles would be dispersed. For the first solution, pelletizing techniques will be used to obtain porous pellets from aqueous suspensions of both mineral and synthetic carbonate particles. The pellets obtained will be impregnated with high-temperature salts. In the second solution, mixtures of salts of high thermal stability will be selected in which carbonate particles or pellets will be dispersed. For the preparation of the porous pellets, freeze granulation techniques will be used to obtain porous and stable pellets from particle suspensions. All prepared materials will be characterized in terms of thermophysical properties and multicyclic behavior. Optimal operating conditions as well as maximum working ranges will be established. These results will be used as parameters for subproject 1.
Subproject 2 has the participation of a multidisciplinary team with expertise in chemistry, solid reactivity, heterogeneous kinetics, physics, and materials science to complete the proposed objectives. They have experience and solvency guaranteed in the execution of national and international projects, in addition to industrial projects, in the field of design and characterization of materials for thermal energy storage.
PHOTOelectrocatalytic systems for Solar fuels energy INTegration into the industry with local resources
01-09-2023 / 31-08-2027
Research Head: Hernán Míguez y Laura Caliò
Financial Source: Unión Europea
Code: HORIZON-CL5-2022-D3-02-06
The PHOTOSINT project presents solutions to the challenges chemical industries are facing in integrating renewable energy sources into their processes. The project will deliver sustainable processes to produce hydrogen and methanol as energy vectors using only sunlight as an energy source and wastewater and CO2 as feedstocks, making the industries more auto-sufficient. The pathway is based on solar-driven artificial photosynthesis, and aims to develop new catalytic earth-abundant materials and modifications of existing ones to improve catalytic processes. Design parameters of the PEC cell will be tuned to maximize solar to fuel (STF) efficiency. Moreover to improve the conversion for industrial implementation, PHOTOSINT will develop a novel way to concentrate and illuminate the semiconductor surface to maximize overall energy efficiency. Perovskite solar PV cells will be integrated to harvest the light to supply the external electrical voltage.
PHOTOSINT is an ambitious project due to precedents in research conducted to date and the low production rate of the desired products. For integrating sunlight energy into the industry, the catalyst will be studied, and then the best one/s will be implemented in prototypes. The obtained results will be used for making scale-up in pilots with tandem PEC cells. These steps are necessary to assess the industrial scale-up feasibility, promoting the increased competitiveness of renewable process energy technologies and energy independence. MeOH and H2 will be tested in engines. Also, an HTPEM fuel cell will be used for electricity generation, and hydrogen will be tested as an alternative fuel for energy generation instead natural gas in melting furnaces avoiding CO2 emissions.
Stable Halide perovskite-based photonic and optoelectronic devices by vacuum and plasma technologies
01-09-2023 / 31-08-2026
Research Head: Angel Barranco Quero / Juan Ramón Sánchez Valencia
Financial Source: Ministerio de Ciencia e Innovación
Code: PID2022-143120OB-I00
Research Team: Vanda Fortio, Victor López, José Cotrino, Ricardo Molina (IQAC), Victor J. Rico, Juan Pedro Espinós, Ana I. Borrás, Francisco J. Aparicio, Carmen López, Agustín R. González-Elipe
PVSkite is a multidisciplinary project whose main objective is to exploit advanced vacuum and plasma techniques for the development of materials, nanostructures, and devices based on halide perovskites. In the case of plasma techniques, we seek to explore proprietary approaches, such as the RPAVD (remote plasma-assisted vacuum deposition) technique, for the development of encapsulation systems, electrode passivation, interfacial engineering, and new electrode formulations for perovskite solar cells. This approach is supported by some very promising recent results of the group on perovskite cell encapsulation and passivation of inorganic electrodes with ultra-thin conformal polymeric films. In the case of vacuum processes, the project will focus on applying the glancing angle deposition technique (GLAD) to the design of anisotropic crystalline perovskites for light polarization control and the structuring of charge transport electrodes.
We also start from some very recent initial results that demonstrate the enormous potential of this approach. The proposed approaches have not been addressed in the current literature, but we believe can have a very important impact on the development of halide perovskite-based materials and devices. The group has more than two decades of internationally recognized experience in the fabrication of functional materials by these techniques and their application in very diverse fields including the development of functional devices (photonics, sensors, energy sensors, etc.).
The project encompasses activities at different levels, combining fundamental and applied research, growth process and materials simulations, synthesis of new materials under design, advanced functional characterization, and device interrogation. The development of a series of laboratory-scale prototypes is a fundamental aspect of the proposal, which will validate the feasibility of the approach. To this end, appropriate platforms and measurement protocols will be designed. The first type of device to be developed will be perovskite cells, stable against water and humidity incorporating all the modifications of interfaces, novel electrodes, and encapsulation elements developed in the project. The second type of device will be polarization-sensitive perovskite optoelectronic devices, also incorporating selected plasma layers to increase their stability. Two types of polarization-sensitive devices will be studied a) polarized light emitting devices and b) polarized light detectors. The project is completed with a preliminary evaluation of the stability in vacuum and in the presence of ionization sources of some selected devices.
For the achievement of PVskites objectives, we count on the collaboration and the express interest of four companies that are directly related to each of the aspects of the proposal. These companies are Arquimea, through its energy division, Lasing SA with a wide experience in the use and development of photonic elements and devices, and Fluxim, a world leader in the study of the environmental stability of solar cells. The fourth company, ALTER TÜV NORD, is interested in the potential application of stable perovskite cells in space.
Influence of the optical environment on persistent luminescence nanomaterials: A new tool for the design of nanobatteries of light
19-05-2023 / 19-11-2024
Research Head: Gabriel S. Lozano Barbero
Financial Source: Fundación BBVA
https://www.redleonardo.es/beneficiario/gabriel-s-lozano-barbero/
The development of societies is linked to their ability to generate artificial light, from torches to today's ubiquitous light-emitting diodes (LEDs). Persistent luminescence (PersL) materials are able to store optical energy in structural defects and generate light long after the excitation source disappears, making them batteries of light. Despite the advantages associated with size reduction, the properties of persistent nanomaterials are far from those of their bulk counterparts used in signaling or ornamentation. This proposal pursues to integrate PersL nanomaterials into transparent thin films and to precisely characterize the charging kinetics and the amount of light emitted during afterglow as a function of the optical environment of the coatings. Photonics has never been explored to control the charging and emission mechanisms that determine PersL, which may have an impact on the development of more versatile color converters, smart labels, anti-counterfeiting elements or optical data storage
Flash Techniques for the Production of High-Entropy Oxides with MAGnetic Properties
01-02-2023 / 31-08-2025
Research Head: Alejandro Fernando Manchón Gordón
Financial Source: Junta de Andalucía
Code: ProyExcel_00360
The FOMAG project focuses on the application of innovative fast sintering techniques, such as Flash Sintering (FS), Reactive Flash Sintering (RFS), and Multifaceted Flash Sintering (MPFS), for the synthesis of high-entropy oxides (HEOs) with technologically relevant magnetic properties. Despite FS being first proposed in 2010, SFR in 2018, and MPFS in 2022, interest in this process has grown significantly in various scientific fields due to its considerable scientific and technological potential
These techniques enable the fabrication of ceramic materials at significantly lower temperatures and times compared to conventional sintering methods, achieved by applying a small electric current through the sample. Furthermore, the specific experimental conditions of Flash techniques allow the production of dense and nanostructured ceramic materials, which can be challenging using conventional methods. Importantly, Flash sintering not only drastically reduces the energy consumption required for ceramic material processing but also extends its applications to new materials for technological purposes. In this context, HEOs represent an emerging class of ceramic materials with equimolar compositions containing five or more cations. The uniqueness of these systems, first proposed in 2015, lies in their extreme chemical complexity coupled with simple crystallography, where atoms arrange in a relatively straightforward crystal structure, overcoming phase separations typical in heavily doped systems. In terms of the local structure, these materials consist of an unusually high number of distinct combinations of metal-oxygen-metal bonds, inherently affecting magnetic interactions based on factors such as coordination geometry, valence, and the types of surrounding metal cations. This results in a wide range of intriguing magnetic responses.
FOMAG proposes the utilization of FS, RFS, and MPFS techniques in producing HEOs with magnetic properties, capitalizing on the inherent advantages of these techniques, particularly in achieving high density in systems where this is particularly challenging.
Development of flexible and high efficiency piezoelectric nanogenerators based on perovskite/PVDF nanocomposites
01-12-2022 / 30-11-2024
Research Head: Rocio Moriche Tirado
Financial Source: Ministerio de Ciencia e Innovación
Code: TED2021-131458A-I00
Research Team: Francisco José Gotor Martínez (ICMS), María Jesús Sayagués de Vega (ICMS), Rosalía Poyato Galán (ICMS), Ana Morales Rodríguez (US), Felipe Gutiérrez Mora (US), Ángela Gallardo López (US)
Application of advanced disinfection processes with nanomaterials in the reduction of impact from urban pressures in the framework of circular economy
01-12-2022 / 30-11-2024
Research Head: Rosa Mosteo Abad (UNIZAR) / Mª Peña Ormad Melero (UNIZAR)
Financial Source: Ministerio de Ciencia e Innovación
Code: TED2021-129267B-I00
Research Team: María Carmen Hidalgo López (ICMS), Francisca Romero Sarria (ICMS), MªPilar Goñi Cepero (UNIZAR) y Encarnación Rubio Aranda (UNIZAR)
Water is one of the natural resources that, due to its limited and variable nature, both in quantity and quality, should be protected with special intensity, in line with the Environmental Objectives that support the ecological transition: sustainable use and protection of water and marine resources, circular economy, pollution prevention and control, and protection and restoration of biodiversity and ecosystems. Studies realized in collaboration with the Confederación Hidrográfica del Ebro, the urban point sources are the pressures that in most cases are the cause of non-compliance
with the environmental quality objectives established by the DMA. This non-compliance are mainly related to microbiological contamination in the receiving waters of these discharges.
Generally, as there is no legal requirement, wastewater treatment facilities do not include disinfection processes that reduce the microbiological load of effluents and, consequently, these agents are incorporated into natural waters, limiting the usemade of them, especially in supplying populations and recreational use (bathing and others). Likewise, such contamination in wastewater limits the possibility of its subsequent reuse, reducing the capacity to increase the availability of water resources. It is important to remark that, water reuse for agricultural irrigation can also contribute to circular economy by recovering nutrients from the reclaimed water and applying them to crops, by means of fertigation techniques. Thus, water reuse could potentially reduce the need for supplemental applications of mineral fertilizer.
Therefore, it is necessary to intensify the wastewater treatment efficiency by non-conventional processes that improve the treated water quality with the final objective of allowing a safe reuse of effluents, taking into account the regulation (EU) 2020/741. On the other hand, the control of more microbiological parameters is essential for a correct analysis of the technologies application. Aware of this need, the AySA group has been developing research projects for many years focus on the research about conventional and non-conventional processes, based on photocatalytic processes, applied for disinfection waters and about the microbiological control in urban wastewater treatment plants. The main objective of this project is to select the best technology for disinfection of treated urban wastewater for full-scale application by the improvement of previously studied advanced oxidation processes in the disinfection of these type of waters. Furthermore, the microbiological control, not only by bacterial indicators conventionally used but also protozoa and endosymbiotic bacteria that are inside amoebae, is consider very relevant in this project since to our knowledge, there are no studies investigating such a wide range of potentially pathogenic micro-organisms. This realistic approach is expected to minimise the impact on the receiving waters and increase the possibility of reuse, reducing the the health and environmental risk.
Design and selection of novel materials for the fabrication of high performance reversible solid oxide fuel cells
01-12-2022 / 30-11-2024
Research Head: Francisco José García García (US) / Juan Gabriel Lozano Suárez (US)
Financial Source: Ministerio de Ciencia e Innovación
Code: TED2021-132057B-I00
Research Team: Francisco José Gotor Martínez (ICMS), María Jesús Sayagués de Vega (ICMS), Yadir Torres Hernández (US), Isabel Montealegre Meléndez (US), Cristina María Arévalo Mora (US), Ana María Beltrán Custodio (US), Eva María Pérez Soriano (US), Paloma Trueba Muñoz (US)
Development of intermittent plasmas ignited by renewable electricity for the CO2 splitting and revalorization processes [RENOVACO2]
01-12-2022 / 30-11-2024
Research Head: Ana María Gómez Ramírez / Manuel Oliva Ramírez
Financial Source: Ministerio de Ciencia e Innovación "Transición Ecológica y Transición Digital"
Code: TED2021-130124A-I00
Research Team: Rafael Álvarez Molina, José Cotrino Bautista, María del Carmen García Martínez (US), Alberto Palmero Acebedo, Agustín R. González-Elipe
CO2 emissions currently represent the 77% of the total greenhouse gas emissions of anthropogenic origin. It provokes a gradual increase in global warming of our planet with catastrophic environmental consequences. There is no doubt about the need to promote a transition toward an economy avoiding the intensive use of fossil fuels, i.e., using the electricity generated from renewable sources as primary source of energy, and favoring alternative and more sustainable chemical processes. The project "Development of intermittent plasmas ignited by renewable electricity for the CO2 splitting and revalorization processes", RENOVACO2, aims at developing atmospheric plasma technologies that use electricity as a direct energy vector to induce chemical processes that are currently carried out through catalytic techniques (i.e., at high pressures and temperatures, using harmful and non-recyclable catalysts). RENOVACO2 is a multidisciplinary project that pursuits the development of novel physical processes for the elimination and revalorization of CO2, especially designed and optimized for their activation by means of renovably energy sources. The proposed technology consist of using atmospheric pressure plasmas to induce chemical reactions in non-equilibrium conditions at atmospheric pressure and in a distributed way.
Photophysical analysis of parameters affecting efficiency and stability of dry processed metal halide perovskite solar cells: activation and degradation processes
01-12-2022 / 30-11-2024
Research Head: Hernán Míguez García / Juan Francisco Galisteo López
Financial Source: Ministerio de Ciencia e Innovación
Code: TED2021-129679B-C22
Research Team: Mauricio Calvo Roggiani, Gabriel Lozano Barbero
Advanced photophysical characterization has proven to be a key tool in the study of the optoelectronic properties of metal halide perovskites. Over the past decade time-resolved absoprtion and emission measurements have unveiled the unique photophysics of this material and have contributed to explain both, their outstanding performance in light harvesting and emitting devices but also its main limitations, such as material instability. These measurements have thus been used as a means to guide materials fabrication beyond trial and error approaches and have contributed to turning perovskites into the fastest growing photovoltaic technology. In this regard, advanced optical characterization will be employed in the present subproject (ESPER2) to bring vacuum thermal evaporated PV devices one step closer to the optimal performance in terms of efficiency as well as stability. A combination of steady state and time-resolved optical characterization experiments will be performed on perovskite films, architectures and devices in order to understand those factors affecting its performance: the presence of crystalline defects (and means to avoid them via compositional changes and passivating agents), the transfer of charges from the perovksite to adjacent charge transporting layers and the presence of photo-induced processes (such as photo activation and degradation) as well as the possibility of using the latter as a means to improve the materials optoelectronic properties. Beyond extracting critical information regarding charge recombination and transport, an optical design will be carried out in order to optimize light harvesting within the device comprising the best performing materials. The proposed characterization will thus help bringing a technology amenable to be used for mass production, such as vacuum deposition, closer to the market demands in terms of efficiency and durability.
Thermochemical Energy storage materials enhanced by microstructural control
01-09-2022 / 30-11-2024
Research Head: Luis Allan Pérez Maqueda / Pedro Enrique Sánchez Jiménez
Financial Source: Ministerio de Ciencia e Innovación
Code: TED2021-131839B-C22
Research Team: Joaquín Ramírez Rico, José Manuel Valverde Millán, Antonio Perejón Pazo
The main objective of the MOTHERESE project is the development of a new concept of thermochemical energy storage based on the "Calcium-Looping" process. The novelty of the concept lies in scaling down the storage component and making it modular, easily integrated in power generation plants of different nature, storable and mobile. Subproject 2 focuses on aspects related to the development of materials suitable for these new operating conditions, as well as their optimization at this new scale.
The aim is to address the development of these materials with emphasis on preparation techniques that favor morphologies and microstructures that optimize (i) the kinetics of solid-gas reactions, in order to reduce residence times, (ii) multicyclic stability, minimizing deactivation by sintering and pore blocking, and (iii) active surface area, maximizing the amount of reagent available for conversion in each cycle. This will be achieved by using freeze casting and freeze granulation techniques, particularly suitable for the fabrication of ceramic structures with open porosity and directed morphology. The use of additives to improve the performance of the material is also considered. Finally, the integration of the active material and additives of high thermal conductivity in stable three-dimensional structures is contemplated, which not only improve the cyclability and efficiency of the active material but also ensure fast and efficient heat transfer, necessary for the modular system. Finally, new operating conditions compatible with the new scale will be explored, from low pressures to high pressures of up to 5 bar, always maintaining a closed cycle that avoids the need for gas separation.
MOTHERESE is committed to the circular economy, and therefore aims to use by-products and waste from other industries as a source of additives and even of the active material itself, CaO, favoring the use of waste. These include steel mill slag, biogenic carbonates (mollusks), cellulosic materials and rice husks (source of SiO2).
To address these objectives, the subproject has a multidisciplinary team of chemists, engineers, physicists and materials specialists with experience in the management and participation in national and international research projects, including relevant projects focused on thermochemical energy storage. In addition, the team has an international network of academic and industrial collaborators that would allow in the exploitation of the results obtained and the proposal of new international projects in this same line.
Towards Digital Transition in Solar Chemistry (SolarChem 5.0): Photoreactors
01-12-2022 / 30-11-2024
Research Head: Sixto Malato Rodríguez (PSA-CIEMAT) / Diego C. Alarcón Padilla (PSA-CIEMAT)
Financial Source: Ministerio de Ciencia e Innovación "Transición Ecológica y Transición Digital"
Code: TED2021-130173B-C43
Research Team: Gerardo Colón Ibáñez, Alba Ruiz Aguirre (PSA-CIEMAT)
The Solar Energy Challenge. Throughout history, the most significant improvements in humanity have been linked to the industrial revolution (IR). Nowadays, we are immersed in the 4th IR “The digitally disruptive era” where Europe is on a transition towards climate neutrality and digital leadership.1 Industry 5.0 aims to position research and innovation to the service of the transition to a sustainable, human-centric, and resilient European industry.2 Solar chemical technologies will radically alter the existing models of industrial production and energy transformation and storage. However, the needed scale is in sight but not yet reached due to the lack of available highly performance and low-cost technologies. SolarChem 5.0 aims to contribute to the 5th IR, laying the foundation basis of the synergy between ecological and digital transition in the framework of Solar Chemistry through: “The development of an innovative Digital Solar Chemistry technology, to convert Earth-abundant resources and pollutants into fuels and chemicals, filling the gap between sustainable and scalable solar-driven technologies”
To achieve this ambitious objective and taking into account the complexity and the project duration our strategy is based on the design of an interdisciplinary consortium formed by four subprojects (SP) that include leading research groups in complementary disciplines such as: Chemistry, Material Science, Bio-catalysis, Photoelectrochemistry, Artificial Intelligence (AI), Solar Technologies and Advanced Characterization. Each SP incorporates a multidisciplinary crew composed by more than one research team from different research institutions, universities, and/or singular facilities.
This subproject dedicated to photoreactors (SP3) will be concentrated in the conceptual design and development of a Solar photoelectrochemical (PEC) reactor for the selection of the most suitable configuration for the reaction and the operation of the solar collector. The research activities of this SP3 will be developed in WP5 and managed by researchers from two different institutions: PSA-CIEMAT (leader of SP3) and ICMSE-CSIC. The “Plataforma Solar de Almería” (PSA) is a European Large Scientific Installation and a Singular Scientific and Technical Infrastructure of Spain (ICTS) with a vast background in the design, construction, and implementation of solar reactors for photochemical reactions, together with outstanding installations. The PSA-CIEMAT team also has extensive experience in the use of ray tracing programs such as TONATIUH and SOLTRACE for the opto-energetic characterization of concentrating solar power systems. Likewise, a set of self-developed solar thermal simulation tools validated in the different low and medium-temperature solar pilot plants available at PSA. In addition, ICMSE-CSIC team will participate in the development of the PEC Cell and the electrode integration.
Triboelectric nanogenerators for raindrop renewable energy harvesting
01-12-2022 / 30-09-2025
Research Head: Ana Isabel Borrás Martos / María del Carmen López Santos
Financial Source: Ministerio de Ciencia e Innovación
Code: TED2021-130916B-I00
Research Team: Gildas Leger, José Cotrino, Ricardo Molina, Juan Ramón Sánchez, Victor Rico, Germán de la Fuente, Juan Pedro Espinós, Antonio José Ginés, Angel Barranco, Luis Alberto Angurel, Jorge Gil, Agustín R. González-Elipe
DropEner aims to develop rain panels, that is, energy collectors from drops that, based on the principle of the triboelectric nanogenerator (TENG), work in outdoor conditions and can be manufactured through scalable and high-performance technologies. The project will demonstrate the application of an innovative concept recently patented by the group Nanotechnology on Surfaces and Plasma (CSIC-US), "Tixel", on the collection of kinetic energy from drops in instant contact with a triboelectric surface integrated into a condenser-like architecture. Therefore, the main objective is to develop a drop energy harvesting panel based on the first TENG of nano and microstructured architectures capable of generating high power density by implementing triboelectric nanogenerator arrays at the microscale, where each nanogenerator produces hundreds of microwatts of power when a high-velocity, high-energy raindrop strikes its surface. The total power output would be equivalent to the sum of the power produced by the individual systems and could potentially reach hundreds of watts per square meter when a well-designed high density array is manufactured. In addition, in a step further in the state of the art for the exploitation of solid-liquid drop energy harvesters, DropEner pursues the development of durable and transparent Tixels fully compatible with solar cells, including Silicon and Third Generation technologies. (such as dye solar cells and perovskite solar cells). The expected advances cover aspects such as the development of surfaces with super-wettability, the exploitation of scalable production routes and processing of materials, the manufacture of transparent drop energy harvesters, the proof of concept of novel designs of triboelectric nanogenerators and the management of energy in multi-source intermittent energy collection systems.
Upcycling of potato peel by-products into sustainable, multifunctional lacquers for food metal packaging (POP-UP)
01-12-2022 / 30-11-2024
Research Head: José Jesús Benítez Jiménez / José Alejandro Heredia Guerrero (IHSM)
Financial Source: Ministerio de Ciencia e Innovación
Code: TED2021-129656B-I00
Research Team: Eva María Domínguez Carmona (IHSM), Mª de la Montaña Durán Barrantes (IHSM), Antonio Heredia Bayona (IHSM), Jorge Rencoret Pazo (IRNAS), José Carlos del Río Andrate (IRNAS), Diego Francisco Romero Hinojosa (IHSM)
POP-UP project aims to provide, in terms of circular bioeconomy, sustainable, safe, and economically viable solutions to the massive use of petroleum-based BPA resins in food packaging through the fabrication of multifunctional, high-performance coatings for metal substrates from inexpensive, underutilized agro-food by-products. In particular, peels resulting from the industrial food processing of potatoes will be used as a bio-renewable resource of suberin monomers to fabricate biodegradable, bio-based lacquers by green and large-scalable technologies (i.e. spray from aqueous solutions and free-solvent, non-catalyzed melting polycondensation) for sustainable and innocuous food packaging. This suberin-based coating will offer same benefits and properties with respect to BPA resins, but it will be designed to be fully non-toxic and with antimicrobial properties. Hence, main objectives are related to improve food security, to contribute to an ecological transition from a linear fossil-based economy to a circular bioeconomy, and to increase agricultural productivity by upcycling plant residues.
DeSign of Multifunctional cAtalysts foR one poT sustainable fuel synthesis from CO2-rich syngas via hybrid Fischer-TropSch/Hydrocracking processes (SMART-FTS)
01-09-2022 / 31-08-2025
Research Head: José Antonio Odriozola Gordón / Tomás Ramírez Reina
Financial Source: Ministerio de Ciencia e Innovación
Code: PID2021-126876OB-I00
Research Team: Luis Francisco Bobadilla Baladrón, Anna Dimitrova Penkova, Francisco Manuel Baena Moreno, José Rubén Blay Roger, Nuria García Moncada, Miriam González Castaño, Ligia Amelia Luque Álvarez
Following the directions of the United Nations Sustainable Development Goals (UNSDG), it is mandatory to take action on this by pursuing affordable and clean energy alternatives (goal 7) to favour sustainable cities and communities (goal 11) while mitigating climate change (goal 13). Indeed, Horizon Europe prioritises low and zero carbon technologies as key objectives for next generation Europe. Based on these premises, biomass, and in particular biomass residues, represent a promising substitute for fossil fuels and an excellent feedstock for low-carbon fuels manufacturing. During its short life cycle, all carbon in biomass comes from the atmosphere and soil and is liberated into the environment when it is burned. Therefore, biomass is considered a carbon-neutral fuel. In addition, biomass-derived fuels are high energy density hydrocarbons which are ideal for aviation, maritime and heavy-duty vehicles in contrast to batteries and electrochemical devices which are suitable for lighter applications and hence complementary to biofuels. In plain words we cannot fly an aircraft on batteries for long distances, but we can power it with sustainable biofuels. Hence biofuels from biomass are meant to play a key role in decarbonising the transport sector. Furthermore, offering a second life to bio-residues is crucial for some communities (i.e. farming and agri-sector) whose market horizons can be expanded by turning a problem “waste” into a profitable “biofuel precursors”. Herein, SMART-FTS is bringing disruptive concepts on biofuel production from bio-syngas to push forward transport decarbonisation in harmony with the circular economy strategy
Development of biochar based heterostructured materials with photofuntional properties for applications in water decontamination and disinfection processes
01-09-2022 / 31-08-2025
Research Head: María Carmen Hidalgo López / Francisca Romero Sarria
Financial Source: Ministerio de Ciencia e Innovación "Generación de Conocimiento"
Code: PID2021-122413NB-I00
Research Team: José Manuel Córdoba Gallego, Concepción Real Pérez, María Dolores Alcalá Gonzalez, José Antonio Navío Santos y Rosa Mosteo Abad (UNIZAR)
In the present research project we propose the development heterostructured photocatalyst systems (ZnWO4/ZnO, WO3/AgBr, WO3/TiO2, Bi2WO6/TiO2, ZnBi2O4/ZnO, Bi4Ti3O12/Bi20TiO32) coupled or supported on biochars (coming from the pyrolysis of olive pruning waste, rice husk and olive stones and allowing a path of revalorization of these wastes), the study of the different synthesis variables and methods, their optimization, and their photocatalytic behavior evaluated in the disinfection of water and degradation of emerging pollutants.
In the last years, new photocatalysts based on heterostructured materials are arising, where semiconductor heterojunctions have been developed to achieve the spatial separation of electrons and holes providing appropriate separation pathways, thus obtaining benefits for prolonged charge carriers lifetime, broadening light absorption and increasing the efficiency of the system. Although these materials have shown good behavior in the visible on the different substrates studied, they generally present moderate or low specific surface area values, and some of them have stability problems after few reaction cycles.
The project proposes the coupling or support of these heterostructured photocatalysts on biochar of different characteristics, with the aim of providing them with higher specific surface areas and increase their effectiveness and stability for their applications as photocatalysts, improving the absorption ability, narrowing the bad-gap where the biochar can act as photosensitizer, improving the electron transport, allowing a better separation of photogenerated carriers and prolonging their lifetime and providing stabilization and photo-stabilization to the systems.
Biochars are carbon-rich materials obtained by thermal treatment of biomass in the absence of oxygen (pyrolysis) and show interesting properties such as high specific surface areas and porosities, and can be tailored by controlling operating conditions, to obtained desired amount and type of functional groups on their surfaces, hydrophobicity or hydrophilicity and surface pH.
The main objectives of the project involve full physico-chemical characterization and optimization of biochar/ heterostructured photocatalysts for the proposed applications under different operation conditions, as solar or visible illumination. The effectiveness of each system in the reduction of emerging contaminants (antibiotic products) and in the inactivation of potentially pathogenic microorganisms usually present in water will be evaluated.
The presence of pathogenic microorganisms in waters is an issue of special concern due to the potential risk of waterborne diseases, and consequently, microbial control is necessary in waters. Likewise, pharmaceuticals and personal care products are commonly used and release to waters. Their potential adverse effects on human health, led to cataloguing them as relevant environmental contaminants belonging to the class of emerging contaminants.
The project is approached from an interdisciplinary point of view and in the context of the circular economy, by revalorizing a waste product (biomass) to develop photocatalysts that provide a solution to a problem (decontamination and disinfection of water) by means of environmentally friendly processes (heterogeneous photocatalysis).
Manufacturing of iron-based porous materials with refractory characteristics for hydrogen purification, use and storage systems
01-09-2022 / 31-08-2026
Research Head: Ranier Enrique Sepúlveda Ferrer (US) / Ernesto Chicardi Augusto (US)
Financial Source: Ministerio de Ciencia e Innovación "Generación de Conocimiento"
Code: PID2021-123010OB-I00
Research Team: Dr. Antonio Gabriel Paúl Escolano (US), Dr. Jesús Hernández Saz (US), Dr. Krishnakumar Balu (US) ICMS: Dr. Francisco José Gotor Martínez
STructured unconventional reactors for CO2-fRee Methane catalytic crackING
01-09-2022 / 31-08-2025
Research Head: Miguel Angel Centeno Gallego
Financial Source: Unión Europea
Code: EU240226_01
Research Team: Maria Isabel Domínguez Leal, Leidy Marcela Martínez Tejada, Svetlana Ivanova
STORMING will develop breakthrough and innovative structured reactors heated using renewable electricity, to convert fossil and renewable CH4 into CO2-free H2 and highly valuable carbon nanomaterials for battery applications. More specifically, innovative Fe based catalysts, highly active and easily regenerable by waste-free processes, will be developed through a smart rational catalyst design protocol, which combines theoretical (Density Functional Theory and Molecular Dynamics Calculations) and experimental (cluster) studies, all of them assisted by in situ & operando characterisation and Machine Learning tools. The electrification (microwave or joule-heated) of structured reactors, designed by Computational Fluid Dynamics and prepared by 3D printing, will enable an accurate thermal control resulting in high energy efficiency. The project will validate, at TRL 5, the most promising catalytic technology (chosen considering technological, economic, and environmental assessments) to produce H2 with energy efficiency (> 60%), net-zero emissions, and decreasing (ca. 10 %) the costs in comparison with the conventional process. The dissemination and communication of the results will boost the social acceptance of the H2-related technologies and the stakeholder engagement targeting short-term process exploitation and deployment. The key to reach the challenging objectives of STORMING is the highly complementary and interdisciplinary consortium, where basic and applied science merge with engineering, computer and social sciences.
The ICMS Group involved in the project will carry out the development of the catalyst from the preparation of powder catalysts to their washcoating on structured supports. CSIC participates as member of the consortium, with the University of Seville participating as an associated entity.
Lanthanide-based bioprobes for MRI and persistent luminescence imaging
01-09-2022 / 31-08-2025
Research Head: Ana Isabel Becerro Nieto / Manuel Ocaña Jurado
Financial Source: Ministerio de Ciencia e Innovación "Generación de Conocimiento"
Code: PID2021-122328OB-100
Research Team: Nuria O. Núñez Álvarez
The overall objective of this project is the development of new contrast agents (CAs) to improve medical diagnostics using two advanced imaging techniques such as magnetic resonance imaging (MRI) and persistent luminescence (PersL) imaging. Specifically, it is planned to develop dual MRI (T1-T2) CAs and PersL bioprobes. The advantage of dual MRI CAs over classical MRI CAs is that they allow two types of resonance images (T1-and T2 weighted images) to be obtained with a single agent. Obtaining both images is very useful as it allows avoiding false positives by cross-validation of both images. On the other hand, the use of probes with PersL significantly improves the signal-to-noise ratio of the luminescence image since, by irradiating the probe outside the organism, autofluorescence of the tissues is avoided. An additional advantage of this type of luminescent probes is that they avoid direct irradiation of living tissues with harmful ultraviolet light. Both types of CAs (MRI and PersL CAs) will consist of uniform nanoparticles (NPs) based on various carefully selected inorganic matrices containing lanthanide ions, whose excellent magnetic and luminescent properties make them ideal candidates for the pursued applications. For MRI CAs, two types of architectures will be addressed, consisting of single-phase nanoparticles (NPs), where the T2 (Dy3+) and T1 (Gd3+ or Mn2+) active cations are in solid solution, and NPs with core-shell architecture, where the T2 ions will be located in the core while the active ions for T1 imaging will be located in the shell. In both cases, phosphate, vanadate and molybdate matrices will be tested, which have been shown to be suitable in the case of T1 or T2 single MRI CAs. In the case of PersL probes, several compounds that have shown excellent luminescence properties in terms of both intensity and persistence duration as bulk materials, will be synthesized as uniform NPs. Specifically, various germanate and gallate matrices doped with lanthanide ions (Pr3+, Yb3+), that emit infrared light within the biological windows, where the radiation is not absorbed by biological tissues or fluids thus improving the penetration depth, will be addressed. Both types of CAs (MRI and PersL CAs) will be submitted to functionalization and bioconjugation processes to provide them with colloidal stability and tumor-specific recognition capabilities. Their biocompatibility will also be tested by studying their cytotoxicity in specific cell lines. Finally, the optimal probes obtained will be applied to MRI and PersL imaging, both in vitro and in vivo, using mice as a model. The research team has extensive experience in the synthesis of lanthanide-based inorganic NPs and has most of the necessary means for their morphological, structural and chemical characterization, as well as for the study of their luminescent properties. In addition, this team has the support of researchers from other institutions who will collaborate in the development of some of the tasks, mainly with regard to bioconjugation, biocompatibility and image recording studies, which guarantees the correct development of the project.
Nanostructured thin films grown by magnetron sputtering deposition with plasmas of Helium and other light gases
01-09-2022 / 31-08-2026
Research Head: Asunción Fernández Camacho
Financial Source: Ministerio de Ciencia e Innovación
Code: PID2021-124439NB-I00
Research Team: María del Carmen Jiménez de Haro
Magnetron Sputtering (MS) is a Physical Vapour Deposition (PVD) methodology typically used for thin films and coatings fabrication. MS commonly employs Ar or Ar/N2-O2 (reactive MS) mixtures as the process gas to be ionized in a glow discharge to create the adequate plasma to sputter a target material. Among a few laboratories we pioneered the introduction of Helium plasmas in the magnetron sputtering technology. Although the deposition rate may be reduced we demonstrated the formation under controlled conditions of nanoporosity and/or trapped gas (He and N2 nanobubbles) in the produced films. In particular solid-films containing gas filled nanopores have several unique characteristics: They allow a large amount of gas to be trapped in a condensed state with high stability, and will provide a route to tailor the over-all films properties. Magnetron sputtering is easy to scale and much cheaper than alternative technologies based on high energy ion implantation. Building on this, we propose to further develop an innovative and versatile bottom-up methodology to fabricate thin films (e.g. Si, C, other metalloids and metals) promoting open porosity or in the opposite stabilizing trapped nanobubbles of the process gas (He, Ne, N2, H2 and their isotopes).
The methodology will be mainly investigated to fabricate unique solid targets and standards of the trapped gas for nuclear reactions studies. Our work will make light gases and their isotopes available in a condensed state and easy-to-handle format without the need for high pressure cells or cryogenic devices. Together with a network of collaborative researchers from the Nuclear Physics and Astrophysics domain we are aiming to bring this application from proof-of-concept to final experiments in large installations facilities. It is also worth to mention that the control of the process from gas filled to nano-porous structures will open additional applications to be investigated in the project such as optical devices, vacuum-UV emitters or catalytic coatings.
The project will introduce innovative process design and control in our magnetron sputtering chambers to work with the different light weight gases newly proposed. Low gas consumption methodologies will be further implemented for scarce isotopes (e.g. 3He). The final goal is to implement an improved MS experimental set-up and to develop the proposed bottom-up methodology in terms of matrix-gas combinations, gas mixtures, variety of supports (e.g. flexible), and self-supported or multilayer designs looking for the innovative applications. An important task is also to determine the MS film growth mechanism. The plasma characterization during the deposition process and the use of the SRIM simulation tool may strongly contribute to a better understanding and control of the growth processes. To understand the microstructure, composition and physical-chemical properties of the novel materials, a complete microstructural and chemical characterization at the nano-scale will be undertaken with a variety of techniques. Of special mention are the advanced electron microscopies (TEM and SEM) including the Electron Energy Loss Spectroscopy and the Ion Beam Analysis techniques for the in-depth elemental composition determination.
Biomass for DEsalination via CApacitive Deionization and Energy Storage, “BioDECADES”
01-01-2022 / 31-12-2022
Research Head: Joaquín Ramírez Rico
Financial Source: Junta de Andalucía
Code: US-1380856
Research Team: Alfonso Bravo León, Manuel Jiménez Melendo, Julián Martínez Fernández
Water resources, global warming and the decline of fossil fuels are three of the main challenges that we as a society will have to address in the next decade. Solutions to these challenges rely on the development of new technologies that allow the efficient use and reuse of water resources, as well as on new, high power and high energy density storage systems to be coupled with renewable sources. These two seemingly unrelated topics currently rely on one technology: carbon adsorbents and electrodes. Both desalination and purification systems as well as supercapacitors and batteries use materials that are based on carbon, their structure modified through physical and/or chemical processes. Biomass is a cheap, widely available precursor for carbon materials, which can be obtained by pyrolysis. Both the choice of biomass as well as the actual process will determine the final properties of the carbon electrode, which can be tailored for targeted applications.
Capacitive deionization (CDI) is an emerging desalination technology with tunable salt removal levels, that uses a small voltage applied across two carbon electrodes to remove ions from solution by means of Electrosorption. The small amount of energy required means that such a system can be powered by a solar panel, making this technology useful in portable and deployable systems. Supercapacitors and batteries also rely on adsorption and/or intercalation mechanisms to store electric charge, in a process that is essentially the same but with a different final target as CDI. Both technologies rely on the use of carbon electrodes, with properties and structure tailored to each of the applications.
This proposal’s main objective is to use biomass residue as a precursor to develop tailored carbon electrodes for electrochemical applications related to energy and environmental technologies, with a focus on two main applications: energy storage in supercapacitor systems and batteries, and desalination via CDI. The main proposed synthesis approach for this electrodes will be the pyrolysis of biomass precursors, with a focus on biomass waste products such as grain husks, peels, pits and stones and other organic waste. In the case of monolithic electrodes, wood and wood-derived fiberboards will be the main focus. Chemical methods will be developed to functionalize the resulting carbons, to improve their capacitance or ion selectivity.
We will build a CDI testing rig to determine desalination behavior, and to correlate this with microscopic information obtained from advanced techniques such as electron microscopy, total scattering diffraction experiments, nitrogen adsorption isotherm, and others. We will test the electrochemical energy storage behavior and correlate it with structural properties and processing conditions. Our goal will be to optimize carbon electrodes derived from biomass for targeted applications, and to develop a menu of biomass derived carbon materials.
New generation of conformal dielectric nanocoatings for emerging electronic devices by plasma technology (PLASMADIELEC)
01-01-2022 / 31-05-2023
Research Head: Francisco Javier Aparicio Rebollo
Financial Source: Junta de Andalucía
Code: US-1381057
Research Team: Ana Isabel Borras Martos, Ramon Escobar Galindo, Lidia Contreras Bernal
Recent advances in nanomaterials and processing techniques are leading to the development of highly miniaturized nanodevices and new functionalities in the field of flexible electronics. The project deals with the development of a new generation of dielectric materials in the form of thin films of nanometric thickness using plasma technology, with the ultimate goal of manufacturing high-performance flexible organic transistors. The proposed plasma deposition methodology is a pioneering technique developed in our laboratory that provides ample control over the dielectric properties and the interaction with liquids of these coatings, as well as allows the conformal deposition on high aspect ratio nanostructures such as nanowires and nanotubes uses in molecular electronics. The proposed plasma technique is fully compatible with the current industrial process used in electronic microdevices and nanocomponent manufacturing. These advantages and the previous results of the proposed plasma technique in the development of photonic materials and sensors support the viability of the project. As a result, PlasmaDielec will establish the bases for the development of new procedures and a new generation of dielectric materials for the future development of flexible electronics.
Biomorphic materials for energy storage (BioMatStor)
05-10-2021 / 31-03-2023
Research Head: Joaquín Ramírez Rico
Financial Source: Junta de Andalucía
Code: P20_011860 - PAIDI 2020
Research Team: María Dolores Alba Carranza, Alfonso Bravo León, Manuel Jiménez Melendo, Esperanza Pavón González
Biomass derived carbon materials will play a key role in several energy conversion and storage technologies in the future, with application in supercapacitors and batteries, power-to-X systems (fuel cells and electrolyzers), CO2 and H2 storage. Large amounts of biomass waste are generated in local agrofood industries. Among these wastes, the overall estimated production of olive stones in Spain is approximately 1,050,000–1,400,000 tons per year (campaign of 2017). The main use of this byproduct has been as solid biofuel for domestic applications, but given its abundance and low cost, this project presents an opportunity to convert what is considered waste into an added value product.
This proposal’s main objective is to develop tailored carbon materials for applications related to energy and environmental technologies, with a focus on three main applications: i) electrochemical energy storage; ii) catalyst supports in fuel cells and electrolyzers; iii) and gas storage and capture, with a focus on both hydrogen and carbon dioxide storage and separation processes. The main proposed synthesis approach for these materials will be the pyrolysis of biomass precursors, with a focus on biomass waste products such as grain husks, peels, pits and stones and other organic waste. A first objective will be to perform a survey of readily available biomass waste materials from regional agrofood industries. A second objective will be the investigation and optimization of pyrolysis and activation routes to obtain carbon materials with tailored properties for each of the applications targeted in this project. Lastly, a third objective is to assess the applicability and the potential for the application of these materials at commercial scale.
Extensive physical and chemical characterization of the obtained carbon materials will be performed and testing of the resulting materials for the targeted applications will allow us to tailor the processing parameters. A scale-up analysis, with definition of materials integration and systems configurations will be performed by means of simulations, as well as technological and industrial applicability evaluation and assessment of the feasibility of the proposed approach in the large scale. BioMatStor develops R&D at different levels of application: fundamental for materials science characterization and manufacturing, and applied science for energy storage systems modeling and characterization. This Project combines Materials Science and Energy Engineering with the goal of obtaining highly performing materials for a wide range of applications in energy production and storage. Such a proposal requires a multidisciplinary approach, as evidenced in the research team and collaborators. We propose a multidisciplinary approach which has its foundation in scientific excellence, responds to societal challenges and may result in a significant technology transfer to the industry. This project also addresses the socio-strategic goals of Horizon 2020 as it aims to contribute to the improvement of our environment through advanced science and multidisciplinary research. It is fully aligned with the objectives and policies of European Union, the Energy Union Energy, H2020, SET Plan and Andalucía region RIS3 objectives.
Design of advanced CataLyst for H2-free hydrodeoxygenation - a rEVolutionary approach Enabling pRactical BIOmass upgrading: CLEVER-BIO
05-10-2021 / 31-12-2022
Research Head: Tomás Ramírez Reina
Financial Source: Junta de Andalucía
Code: P20_00667
Research Team: Luis Francisco Bobadilla Baladrón, José Antonio Odriozola Gordón, Laura Pastor Pérez, Anna Dimitrova Penkova
CLEVER-BIO proposes a revolutionary approach to synergise bio-oil upgrading and Green House Gases (GHG) emissions abatement, setting the grounds for a sustainable chemical technology: waste to fuels/chemicals. We aim to develop novel biomass-derived routes to produce deoxygenated aromatic hydrocarbons – highly important chemical compounds in the biofuels and biochemical industries – from lignin-derived bio-oil via designing of advanced catalysts for the H2-free hydrodeoxygenation (HDO) process. The urgent problem of global warming and the need to decarbonise the transportation and chemical industry in a circular economy context place CLEVER-BIO in a privileged position to become a pioneering approach to contribute towards the development of sustainable societies. CLEVER-BIO will be delivered in 24 months under a comprehensive research program with strong international cooperation and social-scientific impact
Novel piezoelectric nanostructured composite scaffolds for bone regeneration by additive manufacturing
01-09-2021 / 31-08-2024
Research Head: Mario Monzón / Rubén Paz
Financial Source: Ministerio de Ciencia e Innovación
Code: PID2020-117648RB-I00. Plan Estatal 2017-2020 Retos Proyectos I+D+i
Research Team: Óscar Martel, Alberto Cuadrado, María Jesús Sayagués, Rocío Moriche, Ricardo Donate, M. Elena Alemán, Pablo Bordón, Paula Fiorucci, Francisco J. Rodríguez, Joaquín M. Antunes, Chaozong Liu
A pesar del drástico cambio que la ingeniería de tejidos o las terapias con células madre han introducido en las estrategias terapéuticas actuales, todavía existe una falta de funcionalidades en los biomateriales disponibles para el desarrollo de scaffolds para diversas patologías (grandes defectos osteocondrales, osteoporosis, etc.) que afectan a una gran parte de la población. PIZAM aborda este reto aportando scaffolds piezoeléctricos innovadores mediante Fabricación Aditiva (FA) basada en extrusión de material para mejorar la regeneración ósea. Los scaffolds con piezoelectricidad apropiada son capaces de influir positivamente en el proceso de proliferación y diferenciación de células mesenquimales para la regeneración de hueso, ya que existe evidencia científica de la relevancia que tienen las cargas eléctricas superficiales en el proceso de mecanotransducción por el cual las cargas mecánicas influyen sobre la respuesta biomolecular en el tejido óseo (material piezoeléctrico).
Para ello, PIZAM desarrollará materiales innovadores basados en compuestos nanoestructurados conteniendo Ba(Ti,Zr)O3-(Ba,Ca)TiO3 (nanopartículas de óxido cerámico sin plomo con estructura de perovskita). Estos materiales piezoeléctricos se suelen sintetizar mediante una reacción de estado sólido a alta temperatura o métodos basados en disoluciones, que son complejos, costosos y poco respetuosos con el medio ambiente. En PIZAM, la cerámica piezoeléctrica nanoestructurada se obtendrá por mecanosíntesis, una alternativa ecológica con menores costos de producción, desechos y consumo de energía. Las nanopartículas producidas se dispersarán en dos matrices poliméricas: PVDF (biocompatible y con elevada piezoelectricidad) y PLA (biocompatible, biorreabsorbible, baja toxicidad, alto rendimiento mecánico y con cristalinidad/piezoelectricidad ajustable).
Los materiales desarrollados serán procesados para obtener pellets/polvos que se utilizarán como materia prima para la producción de filamentos por extrusión. Estos filamentos se someterán a pruebas de procesabilidad en un equipo de FA de extrusión de material para optimizar los parámetros del proceso mediante algoritmos genéticos e interpolación Kriging. Durante las etapas de fabricación, se llevarán a cabo diferentes caracterizaciones para analizar el efecto de estos procesos en las propiedades fisicoquímicas/piezoeléctricas.
A continuación, se llevará a cabo un proceso de optimización del diseño de los scaffolds para la regeneración del tejido óseo mediante análisis por elementos finitos y algoritmos genéticos. Las estructuras óptimas se producirán por FA y se caracterizarán (propiedades mecánicas y piezoeléctricas). En el caso de scaffolds basados en PLA, se evaluará la evolución de estas propiedades a lo largo del tiempo de degradación. Aprovechando el efecto piezoeléctrico, se realizará una evaluación de las capacidades de los scaffolds para la monitorización en tiempo real.
Por último, el rendimiento biológico de los scaffolds se confirmará mediante un modelo in vitro con células mesenquimales y diferentes estímulos mecánicos para activar el efecto piezoeléctrico: una evaluación inicial sin estimulación (control); estimulación por ultrasonidos; y estimulación en un biorreactor de perfusión. Se analizará la proliferación, viabilidad y diferenciación de las células madre para comprender la relación en el proceso de mecanotransducción y su efecto en la respuesta biológica de los scaffolds.
Design of highly efficient photocatalysts by nanoscale control for H2 production NanoLight2H2
05-10-2021 / 30-06-2023
Research Head: Gerardo Colón Ibañez
Financial Source: Junta de Andalucía
Code: P20-00156 - PAIDI 2020
Research Team: Alfonso Caballero Martínez, Rosa Pereñiguez Rodríguez, Juan Pedro Holgado Vázquez
The main objective of this project is the development of heterostructured catalysts based on highly efficient semiconducting oxides (Nb2O5, WO3, TiO2 and Fe2O3) and g-C3N4, with control at the nanoscale level, and potential application in the photoreforming reaction of alcohols for the production of H2. Furthermore, the aim of this project is to study the optimisation of the catalytic process by means of a multi-catalytic approach, combining thermocatalysis and photocatalysis. The photocatalytic production of H2 is a reaction of great interest from an energetic point of view through the use of a clean and sustainable technology such as photocatalysis. We will try to develop highly efficient systems for hydrogen production. Special attention will be paid to the design of heterostructures that allow the optimisation of the photoinduced process. Likewise, emphasis will be placed on the use of alternative co-catalysts to the traditional noble metals; systems based on transition metals (Cu, Co, Ni), as well as bimetallic structures with noble metals formed into alloys or core-shell. Together with the liquid phase photocatalytic process, the feasibility of a gas phase photoreforming process will be studied, based on recent studies that show the synergistic effect of a photo-thermo-catalytic approach in these processes. In this way, this proposal aims to ambitiously address the increase in efficiency of the photocatalytic process in order to be able to consider this technology on a larger scale. In this sense, in addition to the optimisation studies of the catalysts and the photocatalytic process, its scaling up to a pilot solar plant will be considered as essential.
Gasification and ENergy Integration for User Sustainability (GENIUS)
05-10-2021 / 31-12-2022
Research Head: José Antonio Odriozola Gordón
Financial Source: Junta de Andalucía
Code: P20_00594
Research Team: Luis Francisco Bobadilla Baladrón, Laura Pastor Pérez, Anna Dimitrova Penkova, Tomás Ramírez Reina
GENIUS proposes an innovative approach to transform biogenic residues into a valuable bioenergy carrier. The proposal is based on the combination of modified mature technologies, e.g. gasification, with first-time approached solutions as the continuous aqueous-phase reforming of tars that compromises downstream processes, usually the bottlenecks for upgrading catalytic processes.
The combination of microchannel reactor technologies with state-of-the-art multifunctional catalysts will provide a path to increase the wealth of rural communities on proposing a decentralized approach allowing territory-based solutions for agricultural residues or marginal lands production.
ENIUS focus in the system perspective demanded in HORIZON EUROPE keeping in mind the Objectives for Sustainable Development and industry decarbonisation. GENIUS will be delivered in 24 months under a comprehensive research program with strong international cooperation and social-scientific impact
Integrated nanoscopies and spectroscopies for the analysis of novel functional materials at the nano-scale
05-10-2021 / 30-06-2023
Research Head: Asunción Fernández Camacho
Financial Source: Junta de Andalucía
Code: P20_00239 - PAIDI 2020
Research Team: M. Carmen Jiménez de Haro
The current development of nanomaterials and functional materials in general, as well as their nanotechnological applications, are determined to a large extent by the current capacities on the characterization of microstructure, composition and even properties of the materials at the nano-scale. The project is proposed to promote an innovative research in the microstructural characterization of materials. The nanoscopic and spectroscopic techniques linked to the electron microscopes (electron beam probe), will be integrated together with techniques associated with photon beam (X-rays) and ion beam (IBA techniques) probes. This characterization will be associated with selected functional materials, also within advanced research lines of high current interest, in the topic of coatings and thin films in which the work team has strong experience.
The development and application of the available techniques with multiple probes will be a first central objective, both in the ICMS and in other centers of the Universities of Seville (CITIUS, CNA) and Cádiz (TEM central services). Likewise, through collaborations and measurement time applications, access to other international facilities will be achieved. In the project, selected materials will be available in two emerging technologies: i) Nanoporous thin films and coatings that stabilize gases at ultra-high density and pressure. ii) Catalysts for hydrogen storage and on demand hydrogen generation through the use of liquid organic hydrogen carriers (LOHCs). The advanced characterization proposed in the nano-scale will contribute to the fundamental understanding of the synthesis-microstructure-properties relationships with the final objective of achieving a rational design of new functional materials in the selected priority lines. The project has a direct impact on enabling or emerging technologies such as "nanotechnology" and "advanced materials", as well as on the Andalusian societal challenges and RIS3 objectives in relation to the storage of renewable energies "Topic: Hydrogen and fuel cells".
New multimodal contrast agents for medical diagnostic imaging
05-10-2021 / 30-06-2023
Research Head: Ana Isabel Becerro Nieto
Financial Source: Junta de Andalucía
Code: P20_00182 - PAIDI 2020
Research Team: Manuel Ocaña Jurado, Nuria O. Nuñez Alvarez, María Luisa García Martín
The project aims to design multimodal contrast agents (CAs) for medical diagnostic imaging. The CAs will consist of lanthanide-based inorganic nanoparticles with properties suitable for different bioimaging techniques. The CAs developed will allow obtaining a more rigorous medical diagnosis without the need to inject the patient with several technique-specific CAs. An additional advantage of the proposed probes over commercial CAs is that they allow control of the residence time in the body and their biodistribution, and thus reduce the doses needed, resulting in a clear benefit for the patient. Specifically, dual magnetic resonance imaging (MRI) CAs will be developed with additional functionality as contrast agents for X-ray computed tomography (CT) and luminescence imaging in the near-infrared (NIR) region known as the biological window (650-1800 nm), where radiation is not harmful to tissues and has high tissue penetration power. Several compositions will be tested: phosphates, vanadates, molybdates, and volframates of lanthanide elements such as Gd, Dy, and Ho, which will provide the magnetic functionality and whose high atomic number is optimal for CT. Doping all of them with Nd3+ will allow luminescent imaging in the NIR. The applicability of these probes to medical imaging will be explored by in vivo imaging in mice.
NIR Optofluidic device for liquid analysis
01-12-2021 / 30-11-2023
Research Head: Francisco Yubero Valencia
Financial Source: Ministerio de Ciencia e Innovación
Code: PDC2021-121379-I00 - Proyectos I+D+i "Prueba de Concepto"
Research Team: Juan Pedro Espinós Manzorro, Ramón González García, Victor J. Rico Gavira, Agustín R. González-Elipe
NIRFLOW is a R+D+i Project for the realization of a Proof of Concept in which it is aimed to develop a pre-commercial prototype for the optical analysis in the near infrared of fluids in flow conditions in relevant industrial environments. The project is based on several innovations that are not implemented in conventional NIR apparatus in the market so far. First, to substitute the conventional NIR optics mainly operated by spectrometers based on diffraction gratings or Fourier optics by a selection of the wavelength of analysis based on combinations of continuously variable short and long pass filters designed to tune a NIR passband (regarding center and width). Second, to develop an optofluidic cell, operated in transflectance mode, characterized by a tunable optical pathlength to optimize the info obtained by the different overtones of the characteristic molecules present in the fluid under analysis. This innovation will offer the possibility of more robust statistical analysis than conventional NIR spectroscopy operated with single optical pathlength. Finally, the prototype will be developed within a microfluidic approach with automate analysis concept, for its operation within a wireless remote technology. This three innovations make NIRFLOW a R&D+i project in which part of the knowledge and one of the developments done in previous research project from the Spanish Plan Estatal (MAT2016-79866-R), partially protected by a patent claim, is aimed to be transferred to the society through the development of a precomercial prototype that showed ability of analysis in industrial operational environments, in particular to follow the evolution of fermentation processes linked to wine production.
Validation in a relevant environment of solar-calcination/carbonation reactions for thermal energy storage
01-12-2021 / 30-11-2023
Research Head: Luis A. Pérez Maqueda / Pedro Enrique Sánchez Jiménez
Financial Source: Ministerio de Ciencia e Innovación
Code: PDC2021-121552-C21 - Proyectos I+D+i "Prueba de Concepto"
Spain is one the European countries with the largest solar irradiation and world leader in concentrated solar power (CSP). A significant advantage of CSP technology is its ability to store thermal energy to be used when there is no irradiation. Last generation CSP plants include a storage system based on molten salts (Sensible Heat Storage) that show certain limitations: maximum temperature limited by thermal degradation, storage at high temperature to prevent solidification, corrosion, costs. In our CTQ2017 project we investigated on thermochemical energy storage by calcination (carbonation reactions, calcium looping (CaL) process, using limestone, which is abundant, cheap, non-corrosive, and allows high temperature operation, increasing the thermoelectric efficiency of the plant. Its energy density (~1 MWhr/m3) is larger than that of salts (0.25-0.40 MWhr/m3). A limitation of CaLfor energy storage is the deactivation of CaO with the increasing number of cycles. In our project CTQ20, we proposed several imporvement strategies for achiving high performance: (i) change of calcination/carbonation conditions (calcination temperature decrease and carbonation temperature increase) and (ii) proposal of other carbonates different from limestone, use of additives, use of wastematerials (slags) and low-cost synthetic materials. These lab results are of great interest for its application in CSP, but it requires of validation in a relevant environment. In this project we propose the scale up of the lab results by tests in a pilot plant, the test of a new solar calcinator and the evaluation of the technical-economic feasibility of the technology on an industrial scale. Furthermore, a proof of concept of a novel solar power based cyclone type heat exchanger/reactor will be achive within the project. The concentrated solar radiation will reach the cyclone-type solar calciner through a beam-down system (secondary solar concentrator) from the solar field, made up of 14 heliostats with a total area of 30 m2 from the pilot plant built within the framework of the H2020 SOCRATCES project, in which most of the members of the research team of the coordinated project have participated. The study and development of this proof of concept will make it possible to establish the viability of the design and demonstrate their interest to companies in the energy and cement sectors with a view to a future integration of solar energy in search of a reduction in costs and CO2 emissions. It is based on studies at the concept level developed in the CTQ2017 project with a level of technological maturity TRL 4, and it is estimated that it will advance to levels TRL 5-6. An analysis of the economic viability of the implementation of the new concepts proposed in the framework of the CTQ2017 project will be carried out and a transfer plan will be drawn up. This plan will include the actions to be carried out to favor an effective transfer to the industrial sector. In addition, given the potential for patentability of the technology object of the project, once tested on a relevant scale (proof of concept), a plan for the exploitation and protection of intellectual rights will be developed
Atmospheric Pressure Gliding-Arc Plasmas for Sustainable Applications [FIREBOW]
01-09-2021 / 31-08-2024
Research Head: Ana María Gómez Ramírez
Financial Source: Ministerio de Ciencia e Innovación
Code: PID2020-114270RA-I00 - Proyectos I+D+i "Retos Investigación"
Research Team: José Javier Brey Sánchez (Universidad Loyola), José Cotrino Bautista, Paula de Navascués Garvín, Manuel Oliva Ramírez, Antonio Rodero Serrano (Universidad de Córdoba)
The need to promote an effective transition from an economy based on the intensive use of fossil fuels to another where the development criteria are based on sustainable processes that do not involve the generation of CO2 makes it necessary to develop new processes using the electricity generated from renewable sources as primary source of energy. The project "Atmospheric Pressure Gliding-Arc Plasmas for Sustainable Applications", FIREBOW hereinafter, aims at developing atmospheric plasma technologies that use electricity as a direct energy vector to induce chemical processes that are currently carried out through catalytic techniques (i.e., at high pressures and temperatures, with low yields and harmful by-products). Specifically, FIREBOW pursues the development of a Gliding Arc Atmospheric Plasma reactor (GA) to induce three processes of great industrial and environmental impact, such as the synthesis of ammonia (NH3), the production of hydrogen (H2) and the decontamination of water. Ammonia is the main source to produce fertilizers, which are used in agriculture with an increasing demand according to the increasingly higher needs of foods at global scale. In the case of hydrogen, it is well-known that the path to an economy based on this fuel is one of the challenges of the 21st century. Research in novel techniques for water purification is also increasingly necessary, due to its scarcity and the increase in emergent contaminants, polluting substances such as pesticides, compounds derived from the pharmaceutical and chemical industry, microorganisms and even personal hygiene products that conventional methods are unable to remove completely. FIREBOW proposes, in a first stage, to develop the GA technology through the design, construction, modelling and commissioning of a GA reactor. Possible modifications on the current GA reactors will be explored, considering the effect of the incorporation of piezoelectric materials to induce phenomena of secondary emission of electrons, the modification of the electrode surface materials or the geometry of the system in order to improve the performance of the analysed processes with respect to the current state of the art. The complexity of the basic mechanisms involved in this type of reactors will require a fundamental study of their electrical response and the phenomena of mass and charge transport, as well as an exhaustive characterization and diagnosis of the plasma as a function of operating parameters such as gas flow, interaction between excited species, residence time and other basic operating conditions. Both the experimental and theoretical characterization of the reactor, the latter carried out using computational methods, will be crucial for its correct operation and for the optimization of the proposed processes. In a second stage, the study of the reactions to obtain H2 and NH3 will be approached, with the aim of maximizing the energy efficiency, as well as that for the case of the purification of water. The scientific-technological developments proposed in FIREBOW are of the outmost interest to different socio-economic sectors and in the project they are considered knowledge-transfer actions to companies and entities that have already shown their interest in the proposal.
CO2 recovery through catalytic and thermophotocatalytic processes: reduction of emissions and obtaining methane and other light hydrocarbons (CO2MET)
01-09-2021 / 31-08-2024
Research Head: Alfonso Caballero Martínez / Gerardo Colón Ibáñez
Financial Source: Ministerio de Ciencia e Innovación
Code: PID2020-119946RB-I00
Research Team: Juan Pedro Holgado Vázquez y Rosa María Pereñiguez Rodríguez
This project will carry out various studies and developments related to the CO2 hydrogenation reaction for Synthetic Natural Gas (SNG) and light hydrocarbons production. Thus, methanation and the so-called modified Fischer-Tropsch to olefins (FTO) reactions are becoming very interesting processes under an economic, energy and environmental point of view. Furthermore, the use of green hydrogen as a reducing agent, obtained in turn from renewable sources, represents, in addition to the reduction of greenhouse gas emissions, a way of storing energy from renewable sources, many of which are intermittent and therefore difficult to match with consumption needs.
With all this in mind, this project pursues a multi-catalytic approach comprising thermal-catalysis and thermal photocatalysis in order to achieve high performances, high sustainability and with the lowest costs of production, oriented in all case to a final industrial application. On the other hand, development and optimization of the catalytic materials, considering new heterogeneous catalytic systems based on Ni, Fe, Co, Ru, Au, Pd among other metals, which have shown great potential for this hydrogenation reactions in recent years. Regarding to the catalytic materials, micro and mesoporous supports of variable composition (zeolites, SBA-15, etc.) will be selected, as well as others based on oxides and ABO3 perovskites. For this purpose, a series of recently described preparation techniques will be used (microwave crystallization, autocombustion process, mesostructuring by nanocasting and hierarchical porosity) that allow to obtain high specific surface systems and controlled nanostructure. The combination of different elements in positions A and B of the perovskite structure, which act both as promoters of catalytic systems and as precursors of metal alloys in reduced catalytic systems, will make it possible to obtain materials with tunable, highly varied and versatile catalytic properties.
Dielectric Nanocoatings for Flexible Electronic Devices by Plasma Technology (FLEXDIELEC)
01-09-2021 / 30-08-2025
Research Head: Francisco Javier Aparicio Rebollo
Financial Source: Junta de Andalucía "Programa Emergia"
Code: EMERGIA20_00346
Due to its physical and mechanical characteristics, the emerging technology of flexible electronic devices combines multilayer structures of flexible thin films, 2D nanomaterials, or 1D nanoconductors, such as carbon nanotubes and nanowires. However, these present different limitations related to their degradation against environmental agents and incompatibility with the conventional manufacturing techniques. FLEXDIELEC pursues the development of a new generation of dielectric materials for the development of advanced flexible electronic devices, overcoming these limitations. To this end, a pioneering remote plasma technique will be used, developed by the IP, which regulates the composition and properties of functional organic nanocomposites over a wide range, will be used. This is a dry and room temperature method that ensures complete compatibility with sensitive substrates, such as those with high prospects for implementation in the field of flexible electronics (polymeric materials, fabrics , paper, 2D nanomaterials, organic nanofibers…).
Formic acid as energetic vector: from biomass to green hydrogen
01-09-2021 / 31-08-2025
Research Head: Miguel Angel Centeno Gallego / Svetlana Ivanova
Financial Source: Ministerio de Ciencia e Innovación
Code: PID2020-113809RB-C32 - Proyectos I+D+i "Retos Investigación"
Research Team: Leidy Marcela Martínez Tejada, María Isabel Domínguez Leal
This project is part of the ENERCATH2 coordinated project that aims to integrate a multi reaction catalytic strategy for green-hydrogen and energy related vectors production and use from biomass in order to contribute to the development of sustainable energy technologies that replace current ones derived from fossil sources. Specifically, ICMS project focuses on the production of formic acid as hydrogen related vector Formic acid is a liquid chemical compound with a high gravimetric energy density, which can be safely stored, transported and manipulated using existing hydrocarbon distribution infrastructure.
The main objective of the project is formic acid generation from lignocellulosic biomass and its subsequent dehydrogenation to green hydrogen. For this purpose, it will be intended to develop a series of novel catalysts, preferably based on biomass-derived carbons and/or on non-noble transition metals (V, Ni, Cu, Co etc), active, selective and stable for i) direct and selective oxidation of lignocellulosic biomass, using glucose as representing molecule, either towards the massive production of formic acid, or towards the production of a mixture of formic and co-product levulinic acid, which serves as a starting point for the generation of intermediate platform products and commodities of industrial interest in the production of fuels and polymers and for ii) the dehydrogenation of formic acid, both in liquid and gas phase, for the production of CO-free hydrogen streams.
After the stages of preparation-functionalization and reaction, the catalysts will be structurally and chemically characterized using a wide variety of techniques available by the whole consortium (XRD, XPS, SEM, HRTEM, Raman, DRIFTS, TPR/TPD, TGA, UV-Vis, Textural Analysis). These results, in addition to the in-situ/operando DRIFTS and ATR spectroscopic ones will give us fundamental information of the reaction mechanisms, allowing to establish structure-activity relationships for the studied reactions. The knowledge of these relationships will contribute to the understanding and optimization of the designed catalysts, and the catalytic process involved on the production of sustainable energy vectors proposed in the project.
Nucleation and growth mechanisms on piezoelectric surfaces under acoustic excitation in plasma/vacuum environments
01-09-2021 / 31-08-2024
Research Head: Alberto Palmero Acebedo
Financial Source: Ministerio de Ciencia e Innovación
Code: PID2020-112620GB-I00 - Proyectos I+D+i "Generación de Conocimiento"
Research Team: Rafael Alvarez Molina, Victor J. Rico Gavira, Agustín R. González-Elipe
This project aims at studying atomic nucleation and thin film growth phenomena on piezoelectric surfaces under acoustic excitation in vacuum/plasma environments. Piezoelectric materials are characterized by a non-zero polarization vector when subjected to mechanical deformation and the reverse, a mechanical deformation when subjected to an electrical excitation. While piezoelectric surfaces under acoustic excitation are being used for numerous applications, e.g. raindrop sensors, touch-sensitive screens, or handling of liquids at the microscale, among others, a systematic survey of the literature reveals that only a seminal work published by the research team addresses the effect of acoustic waves in nucleation and growth processes in a plasma environment. There, we demonstrated a strong correlation between the features of the acoustic wave, the associated polarization pattern on the piezoelectric material and the structural features of a surface grown in the presence of a plasma, suggesting that this interaction can be employed as a new methodology to tailor the film nanostructure. Two main sources of interaction are analyzed in this project: i) the mechanical influence of the propagating acoustic wave on the surface-induced mobility processes of ad-atoms, ii) the interaction between the polarization wave on the piezoelectric and the plasma electric field lines, that may affect the transport of charged species and their impingement on the piezoelectric material during growth. In this way, this project focusses on the description, development and understanding of a new phenomenology, and on the provision of the fundamental and theoretical framework to describe this interaction. It is expected that acoustic waves activation and its effect on surrounding plasmas represents a radically new procedure to activate thin film growth and nuclei formation and that the proposed methodology goes beyond any present paradigm in the field of surface physics, envisaging new routes of nanostructuration. Similarly, in the field of plasma dynamics, the possibility of modulating the plasma/surface interaction by acoustic waves is an option that may open alternative procedures for the operation of advanced microplasmas devices or flat plasma displays.
Optimized photonic design of ligand-free perovskite quantum dot based optoelectronic devices
01-09-2021 / 31-08-2024
Research Head: Hernán R. Míguez García / Mauricio E. Calvo Roggiani
Financial Source: Ministerio de Ciencia e Innovación
Code: PID2020-116593RB-I00 PN2020 - Proyectos I+D+i "Retos Investigación"
Research Team: Gabriel S. Lozano Barbero, Juan F. Galisteo López
The motivation of the FreeDot project is three-fold. First, to propose solutions to the specific drawbacks hindering further development of perovskite optoelectronic technology (instability, durability, environmental sensitivity, etc.) by developing nanostructured solar cells and LEDs based on novel porous scaffolds that permit the synthesis of ligand-free nanocrystal assemblies, which show dot-to-dot charge transport while, simultaneously, minimizing their exposure to degrading environments. Second, to prove that improved power conversion efficiency, in the case of solar cells, and enhanced outcoupling and control over the spectral and directional properties of the emitted light, in the case of LEDs, are achievable through the optimization of the optical design also for quantum dot based devices. Finally, the synthesis of ligand-free nanocrystals opens the possibility to study fundamental photophysical properties of quantum dots, which are hindered by the presence of organic cappings in colloidal nanocrystals.
steppiNg towards CIrcular EConomy: REcycling bio-waste into heavy tRansport BIOFUELS (NICER-BIOFUELS)
01-09-2021 / 31-03-2025
Research Head: José Antonio Odriozola Gordón / Tomás Ramírez Reina
Financial Source: Ministerio de Ciencia e Innovación
Code: PLEC2021-008086
Research Team: María Isabel Domínguez Leal, Laura Pastor Pérez
NICER-BIOFUELS aims to create a unique knowledge infrastructure that supports the decentralised, sustainable and cost-efficient conversion of biowastes and textile residues to sustainable Heavy Transport Biofuels (HTB) to contribute towards full transport system decarbonisation. The project targets the development of disruptive technologies that overcome critical technological barriers, increase process efficiency and reduce marginal costs in the bio-waste to HTB conversion process. Following the spirit of circular economy, the overriding idea of NICER-BIOFUELS is to combine CO2 emissions with bio-waste as a carbon pool to produce the next generation of HTB. Such an ambitious goal will be achieved by integrating advanced gasification strategies, unique catalytic technologies and digital tools to deliver fuel processors which are adaptable to feedstock input and HTB demands
PERovskite SEmiconductors for PHOtoNics
01-03-2021 / 28-02-2025
Research Head: Hernán R. Míguez García
Financial Source: Unión Europea
Code: H2020-MSCA-ITN-ETN/0748 Comisión Europea MSCA-ITN
Funded by the Marie Skłodowska-Curie programme, PERSEPHONe is a coordinated training network that aims to equip young researchers with new skills and knowledge regarding the development of a novel photonics technological platform based on metal-halide perovskite semiconductors. These materials present unrivalled optoelectronic properties and can be engineered to achieve a large set of desirable functionalities which may change the roadmap of currently established photonic technologies. They also show great promise for their integration with silicon photonics and silicon-oxynitride-based photonics. The programme will expose 14 early-stage researchers to a wide spectrum of research activities including material synthesis, photonic (and optoelectronic) device and integrated circuit fabrication, characterisation, modelling, upscaling and manufacturing. PERSEPHONe will lay the foundation for a novel photonic technology, strengthening Europe’s position in the field.
Atmospheric Pressure Gliding-arc Plasmas for the Sustainable Production of Ammonia and Hydrogen
01-01-2021 / 31-12-2022
Research Head: Ana María Gómez Ramírez / José Cotrino Bautista
Financial Source: Junta de Andalucía
Code: US-1380977
Research Team: Rafael Alvarez Molina, José Javier Brey Sánchez (Universidad Loyola), Jesús Cuevas Maraver (US), Alberto Palmero Acebedo, Juan F. Rodríguez Archilla (US)
The project “Atmospheric Gliding-arc Plasmas for the Sustainable Production of Ammonia and Hydrogen”, hereinafter ARCPLAS, aims to develop gas chemical transformation processes through atmospheric pressure plasma technologies that use electricity as a direct energy vector. Specifically, the objective is to fine-tune a Plasma Atmospheric Gliding Arc Reactor (PAAD) to induce two processes of great industrial and environmental impact, such as the synthesis of ammonia (NH3) and the production of hydrogen (H2). Ammonia is the base substance of fertilizers used in agriculture, and its demand is increasing in line with world food needs. Regarding hydrogen, it is well known that the path towards an economy based on it is one of the challenges of the 21st century. ARCPLAS proposes, in a first stage, to develop PAAD technology through the design, construction, modelling and commissioning of a gliding arc reactor. The complexity of the basic processes involved in this type of reactors will require a fundamental study of their electrical response and mass and charge transport phenomena, as well as an exhaustive characterization and diagnosis of the plasma based on parameters such as gas flow, interaction between excited species, residence time, chemical characteristics of the gases involved and other basic operating parameters. Both the experimental and theoretical characterization of the reactor, the latter carried out using computational methods, will be essential for its correct operation and optimization of the processes. In a second stage, the study of the reactions to obtain H2 and NH3 will be addressed, with the aim of maximizing their chemical yield, as well as the energy yield of the reactor. Finally, possible modifications of the PAAD reactor will be explored, contemplating the effect of the incorporation of piezoelectric materials to induce secondary electron emission phenomena, the modification of the surface of the electrodes or the geometry of the system in order to promote an improvement in the performance of the processes studied.
Ceramics in a FLASH: The new route for environmentally efficient ceramic processing
01-01-2021 / 31-12-2022
Research Head: Luis A. Pérez Maqueda
Financial Source: Junta de Andalucia
Code: P18-FR-1087 "Frontera"
Research Team: M. Jesús Diánez Millán, Pedro Enrique Sánchez Jiménez
The CeramFLASH project proposes the novel ceramic processing techniques Flash Sintering (FS) and Reaction Flash Sintering (RFS) for the synthesis and preparation of ceramics with technological interest such as solid electrolytes, piezoelectric or hard ceramics. These techniques allow the preparation of ceramic materials in mere seconds at significantly lower temperatures than required by conventional sintering techniques simply by circulating a small electric current under moderate electric fields. This advantage makes it possible to reduce the considerable energy consumption required current ceramic processing techniques. Additionally, it facilitates the preparation of ceramics difficult to obatin in dense and nanostructured form by conventional methods, such as compounds of low thermal stability or compounds that require very high sintering temperatures.
Finally, CeramFLASH aims to use alternating fields with oscillation frequency as well as intelligent control methods based on the sample response to improve the control of microstructural characteristics of resulting ceramics. Although the FS technique was first discovered only 8 years ago, and the RFS was first proposed in 2018 by our group, there is rising interest in this process due to its great scientific and technological potential.
Surface functionalization and diffusion models of germination factors in plasma-treated seeds
01-01-2021 / 31-12-2022
Research Head: María del Carmen López Santos / Antonio Prados Montaño (US)
Financial Source: Junta de Andalucía
Code: US-1381045
Research Team: Agustín Rodríguez González-Elipe, Francisco Yubero Valencia
PLASMASEED addresses the inclusion of vacuum and plasma technology for the surface functionalization of seeds as an effective and clean strategy to make crops less dependent on environmental changes. The aim is to analyze the basic factors and mechanisms that affect the improvement of germination by treating the seeds from a multidisciplinary approach that combines basic concepts of biophysics, advanced characterization and vacuum and plasma processing. The effect of electric fields associated with plasmas and their physical-chemical features, the influence of the diffusion of other germination factors besides water (oxygen, light, etc.), the diffusion of nutrients such as nitrates or other species of interest for germination, etc., are experimental factors that are simulated using Monte Carlo procedures and statistical mechanics to propose holistic models of diffusion of germination factors through seed membranes and the influence of surface treatments by plasma techniques to modify and/or control such processes.
ADVanced convErsioN of biogas To acetic acid: catalytic solUtions for a low caRbon sociEty (ADVENTURE)
01-10-2020 / 30-09-2023
Research Head: Laura Pastor Pérez
Financial Source: Ministerio de Ciencia e Innovación
Code: PID2019-108502RJ-I00
ADVENTURE represents a new concept to convert biogas from organic waste into high-value industrial chemicals such as acetic acid (AA) in an environmentally and economically viable manner. AA is a precursor for many fine chemical compounds with a wide range of applications including paints and coatings manufacturing, plastics and water-based adhesives production among many others, representing a very versatile platform molecule for the chemical industry. Traditionally, AA is produced at a commercial scale through an indirect route with a considerable global CO2 footprint. In this regard, the main target of ADVENTURE is to re-design the AA production route introducing biogas as initial feedstock - a completely new approach that synergises CO2 utilisation with fine chemicals synthesis.
In this context, ADVENTURE will tackle three main challenges: (i) A global challenge the environmental concerns associated with the emission of Greenhouse Gases (GHG); (ii) An industrial opportunity the problem of economic sustainability of the biogas industry by offering viable pathways for conversion of low-value feedstock into added-value biochemicals at industrial scale; and (iii) A fundamental scientific challenge the inexistence of AA production from biogas, by introducing two new revolutionary routes for AA production: an intensified indirect route using microchannel reactors and a direct route enabled by plasma catalysis. In order to accomplish these ambitious goals, a new generation of advanced multifunctional catalysts able to deliver the targeted products with high activity, selectivity and long-term durability will be designed to guarantee the success ADVENTURE.
Magnetron Sputtered Innovative coatings for solar selective absorption
01-06-2020 / 31-12-2024
Research Head: Juan Carlos Sánchez López / Ramón Escobar Galindo (Abengoa Solar New Tecnologies, S.A.)
Financial Source: Ministerio de Ciencia, Innovación y Universidades
Code: PID2019-104256RB-I00 "Retos Investigación"
Research Team: Cristina Rojas Ruiz, Belinda Sigüenza Carballo
The climatic change produced by the gas pollutants emissions and the greenhouse effect along to the short mid-terme depletion of the energy fosil fuels make necessary the search of alternative energy sources, clean and renewable. Among them, the solar energy is one the best options due to the mayor availability to generate heat and electricity.
The goal of the present project is the development of new solar multilayered absorber coatings based on chromium and aluminium nitride (CrAlN). The good oxidation resistance and thermal stability of CrAlN, together with a nanostructured design will ensure a good optical performance (high absorptance and low emissivity) and increase their durability at high temperature. The increment of the working temperature (T>550ºC) will improve the efficiency and reduce the costs of the solar thermal power plants, make them more competitive. The High Power Impulse Magnetron Sputtering technique (HiPIMS) will be used for the preparation of the coatings. This recent innovation of the conventional magnetron sputtering technology allows increasing the film density and compactness thanks to an increased ionization of the plasma. These properties are interesting for the improvement of the adhesion to the substrate and decrease the thermal degradation. In addition to abovementioned strategy, other alternative configurations changing the nature of the material absorber (metal oxynitrides and carbides nanocomposites) would be tried.
The project will comprise all the stages, from the synthesis of the material components of the solar selective structures, design and simulation of the optical behaviour, to the validation in conditions similar to the final application (both in lab and field tests). The structural and chemical characterization, the evaluation of the thermal stability and oxidation resistance will run simultaneously with the aim of optimizing the solar absorber selective coatings with the best performance and durability.
Plasma technology for efficient and DURAble waterproof perovskite SOLar cells
01-06-2020 / 31-05-2023
Research Head: Juan Ramón Sánchez Valencia / Maria del Carmen López Santos
Financial Source: Ministerio de Ciencia e Innovación
Code: PID2019-109603RA-I00 "Retos"
Research Team: Juan Pedro Espinós Manzorro, Xabier García Casas, Víctor López Flores, Javier Castillo Seoane
Solar cells – devices that transform sunlight into electricity – are of vital interest for the sustainable future of the planet. During the last years and aware of this fact, the scientific community has made a great effort to improve the efficiency of these devices. A particular example of a solar cell that contains an organometallic halide perovskite as light absorber has focused the attention of the scientific community during the last decade due, above all, to its high efficiency and low cost. This solar cell technology is a promising alternative to currently existing ones (based on Si and chalcogenides), although they face a scientific and technological challenge that has not been solved in 10 years since its discovery: for the commercial realization of the perovskite cells possible, they need to achieve higher stability, durability and reproducibility. The main problem lies in the high sensitivity of these perovskites to oxygen and environmental humidity, which produce a rapid degradation of the cell’s behaviour in an extremely short time, making commercialization unfeasible.
DuraSol seeks to address this great scientific and technological challenge by manufacturing cell components using vacuum and plasma technology. These methodologies are industrially scalable and present great advantages over solution methods (the most used), among which are: their high versatility, control of composition and microstructure, low cost, environmentally friendly since they do not require solvents, do not produce pollutant emissions and are compatible with current semiconductor technology.
The main objective of DuraSol is the fabrication of waterproof perovskite solar cells by integrating components manufactured by vacuum and plasma methodologies in the form of thin films and nanostructures, which act as hydrophobic sealants. The viability of DuraSol is based on recent results that demonstrate that plasma-assisted synthesis of different components of the solar cell can be one of the most promising ways to increase its stability and durability, which is today the bottleneck that prevents their commercialization. It is worth to highlight that there is no example in the literature about this synthetic approach, and this opportunity is expected to demonstrate the advantages and versatility of this innovative methodology in a field of very high impact. The research proposed in DuraSol falls within the priority areas of the European Union Horizon 2021-2027 program and responds to several of the challenges proposed in this call for “Energía segura, eficiente y limpia” (Challenge 3) and “Cambio climático y utilización de recursos y materias primas” (Challenge 5).
CO2 como fuente de carbono para la producción de compuestos químicos de alto valor añadido
01-02-2020 / 31-01-2022
Research Head: José Antonio Odriozola Gordón / Svetlana Ivanova
Financial Source: Junta de Andalucía
Code: US-1263288
Research Team: Anna Dimitrova Penkova, Ligia Amelia Luque Alvarez, Débora Álvarez Hernández
Design and selection of novel materials for high performance Solid Oxide Fuel Cells
01-02-2020 / 31-01-2022
Research Head: Francisco José García García (US)
Financial Source: Junta de Andalucía
Code: US-15382
Research Team: Francisco J. Gotor Martínez
Solid oxide fuel cells (SOFCs) are one of the most promising and environmentally friendly technologies for the efficient generation of electricity from natural gas and other fossil fuels (hydrocarbons). SOFCs prevent direct fuel combustion, resulting in much higher conversion efficiencies than those obtained by thermomechanical methods. However, various technical difficulties such as the poisoning of the anodes by hydrocarbons, the chemical stability and mechanical integrity of the electrolytes and the high operating temperature, which reduces the selection of materials and makes the technology more expensive, have prevented their large-scale exploitation. A vital component in SOFCs is the anode, where the electrocatalytic reactions that convert the chemical energy of the fuel into electrical current take place. The main problems faced by anodes are related to (i) their durability, (ii) gas diffusion and electrical transport and (iii) resistance to chemical poisoning by carbon and sulfur present in hydrocarbons. Another critical component is the electrolyte, which allows the diffusion of oxide ions from the cathode to the anode. The main characteristics that the electrolyte must present are (i) high ionic conductivity, but negligible electronic conductivity, (ii) good mechanical properties and (iii) stability in reducing and oxidizing atmospheres. Therefore, the wide application and use of this clean technology requires the use of materials for anodes and electrolytes with physicochemical and mechanical properties that allow overcoming the current limitations. The present project aims to address some of the problems discussed above through the development of new anodes resistant to poisoning in the presence of hydrocarbons and the use of electrolytes with improved mechanical properties thanks to the design of new architectures. In this context, the cheap, versatile and simple synthesis by mechanochemical methods of new anodes based on double perovskites of composition PrBaMn2-jXjO5+δ (PBMXO), with X = Mn, Co, Ni, or Fe and 0 < j <0.5, and the design and manufacture of laminated electrolytes with mechanical reliability, without compromising their ionic conductivity, are proposed.
Plasma technology for the development of a new generation of hole transport layers in perovskite solar cells
01-01-2020 / 31-12-2022
Research Head: Juan Ramón Sánchez Valencia (US)
Financial Source: Junta de Andalucía
Code: US-1263142 "Emergente"
Research Team: Angel Barranco Quero, Juan Pedro Espinós Manzorro, Cristina Rojas Ruiz, José Cotrino Bautista
Third generation solar cells (SCs) are nanotechnological devices that directly convert sunlight into electricity and represent the paradigm of research in renewable energies, the use of which will depend on the energy future of the planet. Recently, a particular example of SCs containing an organometallic halide perovskite as a light absorber have attracted the attention of the scientific community due, above all, to their high efficiency and low cost. These characteristics make them a promising alternative to current cells (Si and chalcogenides). However, for the commercial realization of perovskite cells, it is necessary to achieve greater stability, durability and reproducibility. The most important advances have been achieved due to the intense research on the elements that integrate a SC: electron transport layer, perovskite and hole transport layer. Specifically, this latter element has been crucial for its evolution after the implementation of solid state hole conductors.
PlasmaCells pursuits to address for the first time the synthesis of a new family of hole transporters by vacuum and plasma techniques. These methodologies are industrially scalable and have great advantages over solution methodologies (the most used), among which stand out: their high versatility, composition and microstructural control, low cost, are environmental friendly since they do not require solvents, do not produce polluting emissions and are compatible with current semiconductor technology.
The main objective of PlasmaCells is the integration of these new plasma-processed hole transport layers into perovskite SCs. The importance of the project is based on recent results obtained by the Principal Investigator (PI) that demonstrate that the proposed approach may be one of the most promising ways to increase the stability, durability and reproducibility of these SCs, which currently represent the bottleneck that prevents their industrialization. It should be noted that there is no example in the literature of this synthetic approach for the development of hole transporters. It is expected that this opportunity will allow to demonstrate the advantages and versatility of this innovative methodology in a high-impact field, which is framed within the priority areas RIS3 Andalucia and in the PAIDI 2020 of sustainable growth, energy efficiency and renewable energies.
Sustainable Smart De-Icing by Surface Engineering of Acoustic Waves | SOUNDOFICE
01-11-2020 / 31-10-2024
Research Head: Coordinador ICMS: Ana Isabel Borrás Martos
Financial Source: European Commission Horizon 2020
Code: H2020-FET-OPEN/0717
Research Team: Agustín R. González-Elipe, Juan Pedro Espinós, Francisco Yubero, Ángel Barranco, Víctor Rico, María del Carmen López Santos
Icing on surfaces is commonplace in nature and industry and too often causes catastrophic events. SOUNDofICE ultimate goal is to overcome costly and environmentally harmful de-icing methods with a pioneering strategy based on the surface engineering of MHz Acoustic Waves for a smart and sustainable removal of ice. This technology encompasses the autonomous detection and low-energy-consuming removal of accreted ice on any material and geometry. For the first time, both detection and de-icing will share the same operating principle. The visionary research program covers the modeling of surface wave atom excitation of ice aggregates, integration of acoustic transducers on large areas, and the development of surface engineering solutions to stack micron-size interdigitated electrodes together with different layers providing efficient wave propagation, anti-icing capacity, and aging resistance. We will demonstrate that this de-icing strategy surpasses existing methods in performance, multifunctionality, and capacity of integration on industrially relevant substrates as validated with proof of concept devices suited for the aeronautic and wind power industries. SOUNDofICE high-risks will be confronted by a strongly interdisciplinary team from five academic centers covering both the fundamental and applied aspects. Two SMEs with first-hand experience in icing will be in charge of testing this technology and its future transfer to key EU players in aeronautics, renewable energy, and household appliances. An Advisory Board incorporating relevant companies will contribute to effective dissemination and benchmarking. The flexibility of the R&D plan, multidisciplinarity, and assistance of the AdB guarantee the success of this proposal, bringing up a unique opportunity for young academia leaders and SMEs from five different countries to strengthen the EU position on a high fundamental and technological impact field, just on the moment when the climate issues are of maxima importance.
*Participantes
- INMA: Instituto de Nanociencia y Materiales de Aragón, Spain
-UNIZAR: Universidad de Zaragoza, Spain
-TECPAR: Fundacja Partnerstwa Technologicznego Technology Partners; Poland
- IFW: Leibniz-Institut Fuer Festkoerper- Und Werkstoffforschung Dresden E.V.; Germany
-TAU: Tampereen Korkeakoulusaatio SR; Finland
- INTA: Instituto Nacional De Tecnica Aeroespacial Esteban Terradas; Spain
- Villinger: VILLINGER GMBH, Austria
- EnerOcean: EnerOcean S.L., Spain
Adaptive multiresponsive nanostructures for integrated photonics, piezo/tribotronics and optofluidic monitoring | AdFunc
01-06-2020 / 31-05-2023
Research Head: Angel Barranco Quero / Ana Isabel Borrás Martos
Financial Source: Ministerio de Ciencia e Innovación
Code: PID2019-110430GB-C21 - Proyectos I+D+i "Generación de Conocimiento"
Research Team: José Cotrino Bautista, Victor J. Rico Gavira, Francisco Yubero Valencia, Juan Pedro Espinós Manzorro, Agustín R. González-Elipe
AdFUNC is a highly interdisciplinary project whose main objective is to achieve significant progress in two areas at the frontier of Materials Science: the development of multi-response sensors and light-activated energy systems. The common denominators of AdFUNC are the intelligent design of complex architectures at the nanoscale and the development of laboratory scale demonstrators.
We are convinced that the project opens a window of opportunity for us to carry out research that can be classified into four areas: i) Applications and devices: We will develop the recently discovered tribotronic and piezotronic effects to manufacture self-powered sensor devices. With these materials, in combination with several advanced photonic sensing and spectro-electrochemical technologies, we will expand the efficiency, multiactuation and multiresponse of optofluidic adaptive systems. These systems, maintaining a common architecture, will present a differentiated response to diverse and complex real scenarios, which will be simulated in the project (environmental alterations such as spills, accidents, chemical or explosive threats).
Another fundamental aspect of the project are the photovoltaic devices, which will be optimized to be able to work in low light conditions, and mechanical energy collectors and devices that are capable of coupling light and movement to the activation of the water electrochemical decomposition. ii) Nanomaterials: Adfunc is a project where a team of specialists in the development of supported nanostructures by different technologies come together. This will allow us, for the first time, to implement a set of 3D nanoarchitectures (nanowires, nanotubes, core@shell) and the design of materials with controlled nanoporous structures (sculptural layers, nanochannels, porosity associated in several scales, porous optical multilayers, pioneering developments of metalloorganic networks (MOFs) in porous photonic structures) directly to the improvement of the active components of the project devices. Iii) Strategy: The project gives us the opportunity to work simultaneously on new synthetic routes, advanced characterization of materials and properties, integration of materials into devices, and this while simultaneously obtaining modeling and simulation information. iv) Perspective of scalability: In all cases, methods and techniques compatible with established industrial processes will be used, such as plasma and vacuum, typical of the optoelectronic and microelectronic industry, and synthesis processes in solution. Another interesting aspect is the possibility of introducing plastics and polymers to manufacture devices, which may allow the valorization of waste from the plastic industry, in an effort of circular economy in which researchers of the project are committed.
AdFunc is only possible thanks to the joint effort of a large number of researchers, mostly from ICMS-CSIC and the Pablo de Olavide University, which is completed by a group of researchers from other national and international institutions with complementary experience and interest. It is precisely the coordination of such a large number of specialists (25 doctors in the two subprojects) that allows us to propose the development of such a complete and ambitious set of activities.
Proton conducting ceramics for high efficiency reversible electrolyzers and power to X applications
01-06-2020 / 31-05-2023
Research Head: Joaquín Ramírez Rico / Ricardo Chacartegui Ramírez
Financial Source: Ministerio de Ciencia e Innovación
Code: PID2019-107019RB-I00 "Retos de la Sociedad"
Research Team: Alfonso Bravo León, Manuel Jiménez Melendo, Julián Martínez Fernández, Miguel Torres García
PROCEX is aimed at the Social Challenge 3 “Secure, Clean and Efficient Energy”. It aims to open a new pathway for high-efficiency reversible electrolyzers for intermediate temperatures (around 500ºC). Its successful development would open a very promising pathway for energy storage systems in PV and Wind facilities with outstanding characteristics, round-trip efficiencies (75% or higher), and Energy Returned On Investment (>10). These values are much higher than those that can be reached with state of art of thermal energy storage systems. Besides, such a high efficiency concept electrolyzer would have a huge field of application for H2 production and application in the chemical industry. To develop such systems, several materials challenges need to be solved. In particular, novel electrolytes formulations with reduced electronic conductivities are needed.
The project is aimed at the identification and demonstration of new proton conducting ceramic materials that will have reduced electronic leakages in electrolysis operation, based on doping and co-doping strategies in barium cerate and zirconate systems. Emphasis will be placed not only in improving the efficiency but also the durability of such materials. The project will demonstrate the manufacturing of material and electrolyte at laboratory level and it will study the main reaction mechanisms developing models for their understanding and to support the pathways for concept application and scaling up. The project departs from results presented in literature this year that are fully aligned with capacities and previous experience of the participating R&D teams. The project will go further from these results extending the material compositions to develop, tailoring them to specific applications, widening the understanding of the reactions mechanisms and the effects of materials as well to the operation in the materials (i.e. degradation and aging effects). From this approach, within the project new models are expected to be developed and validated and the integration of the concept in different applications will be assessed. The ambition of the project requires a multidisciplinary approach that is developed by two R&D teams, from Material Science and Energy Engineering areas with all the capacities required for the successful development of the project: manufacturing, testing modelling and develop the new concepts and with expertise in materials processing and characterization, electrochemical models, and energy storage systems.
Three-dimensional nanoscale design for the all-in-one solution to environmental multisource energy scavenging | 3DSCAVENGERS
01-03-2020 / 28-02-2025
Research Head: Ana Isabel Borrás Martos
Financial Source: Unión Europea
Code: H2020-ERC-STG/0655 STARTING GRANT
https://3dscavengers.icms.us-csic.es/
Thermal and solar energy as well as body movement are all sources of energy. They can be exploited by advanced technology, obviating the need for battery recharging. These local ambient sources of energy can be captured and stored. However, their low intensity and intermittent nature reduces the recovery of energy by microscale instruments, highlighting the need for an integrated multisource energy harvester. Existing methods combine different single source scavengers in one instrument or use multifunctional materials to concurrently convert various energy sources into electricity.
The EU-funded 3DScavengers project proposes a compact solution based on the nanoscale architecture of multifunctional three-dimensional materials to fill the gap between the two existing methods. These nanoarchitectures will be able to simultaneous and individual harvesting from light, movement and temperature fluctuations. 3DScavengers ultimate goal is to apply a scalable and environmental friendly one-reactor plasma and vacuum approach for the synthesis of this advanced generation of nanomaterials.
CO2 valorization: obtaining hydrocarbons through catalytic hydrogenation processes
01-02-2020 / 31-01-2022
Research Head: Alfonso Caballero Martínez / Juan Pedro Holgado Vázquez
Financial Source: Junta de Andalucía
Code: US-1263455
Research Team: Gerardo Colón Ibáñez, Rosa Pereñíguez Rodríguez, Andrew M. Beale (UCL), Angeles M. López Martín, Francisco Jesús Platero Moreno
This project will carry out several studies and developments related to the reduction of CO2 to valuable products, such as methane, light olefins, gasolines and other functionalized hydrocarbons, of economic, energetic and environmental interest. The use of hydrogen as a reducing agent, obtained from renewable sources, in addition to the reduction of greenhouse gas emissions, is a way to store energy from renewable sources, many of which are intermittent and therefore difficult to match with consumption needs.
Therefore, this project proposes the development of new heterogeneous catalytic systems based on Ni, Fe, Co, Ru and In, among other metals, which have shown in recent years a great potential for this hydrogenation reaction. Given the bifunctional character of the reaction mechanisms involved in these reactions, micro and mesoporous supports of variable composition (zeolites, SBA-15, etc.) will be selected, as well as others based on ABO3 perovskite structure. For this purpose, a series of recently described preparation techniques (Microwave Crystallization, Self-Combustion Process, Mesostructuring by Nanocasting and Hierarchical Porosity) will be used to obtain systems with high specific surface area and controlled nanostructure. The combination of different elements in the A and B positions of the perovskite structure, acting both as promoting agents of the catalytic systems and as precursors of metallic alloys in the reduced catalytic systems, will allow obtaining materials with modulable, varied and versatile catalytic properties.
Modeling and implementation of the freeze casting technique: gradients of porosity with a tribo-mechanical equilibrium and electro-stimulated cellular behavior
01-02-2020 / 31-01-2022
Research Head: Yadir Torres Hernández (US) / Juan Carlos Sánchez López
Financial Source: Junta de Andalucía. Universidad de Sevilla
Code: US-1259771
Research Team: Ana María Beltrán Custodio, Alberto Olmo Fernández, Paloma Trueba Muñoz, María de los Ángeles Vázquez Gámez
Commercial pure Titanium (c.p. Ti) and Ti6Al4V alloy are metal biomaterials with the best properties for clinical repair bone tissue. However, despite their advantages, 5-10 % of implants fail during the five years post-implantation. They are mainly associated with stress shielding (difference stiffness between bone and implant), the use of design criteria (fracture and fatigue) not suitable for biomaterials, the tribo-corrosion phenomena in service conditions and the interface problems (micro-movements and / or the presence of bacteria) that limit the capacity of osseointegration. This project proposes the manufacture and implementation of a simple and economical device to obtain cylinders with controlled (gradient) and elongated porosity by the freeze casting technique. Finite element models will be developed to estimate the geometric growth of the ice dendrites and the mechanical behaviour of the porous cylinders (distribution of stresses and deformations), using real-time radiographs of the directed freezing process, as well as the parameters that characterize the microstructure (amount, size and morphology of porosity) and compression behaviour (stiffness and yield strength). In addition, the generation of surface roughness patterns by ion sputtering is proposed, with the aim to improve the close bond between the implant and the bone tissue. Furthermore, suitable in-vitro protocols are proposed to evaluate cytotoxicity, adhesion, differentiation and proliferation cell. Finally, a bio-impedance measuring system will be developed in order to rationalize the influence of porosity, finished surface and electrical stimulus on the in-situ behaviour of osteoblasts. In this context, the main objective is to manufacture cylinders with a controlled porosity and modified surface, with enhanced biomechanical, tribo-corrosive and biofunctional balance (in-growth and osseointegration of the bone tissue and the implant).
New materials for energy storage of Concentrated Solar Power using Calcium-Looping (SOLACAL)
01-02-2020 / 30-04-2022
Research Head: Antonio Perejón Pazo / José Manuel Valverde Millán (US)
Financial Source: Junta de Andalucía
Code: US-1262507
Research Team: María Jesús Diánez Millán, Luis A. Pérez Maqueda, Virginia Moreno García
This project is focused on the performance of new CaO-based materials during calcination/carbonation cycles (Ca-Looping) under realistic energy storage conditions in concentrated solar power plants (CSP).
In order to simulate realistic conditions, thermogravimetric instruments are used, which are able of employing high heating and cooling rates and different atmospheres of gases. In this way, the results obtained are truly representative and can be extrapolated to practical operating conditions in CSP plants. The multicycle reactivity of limestone and dolomite samples is studied. These samples are modified by mechanical and acetic acid treatments that can improve their reactivity. Moreover, it has been shown that the presence of MgO in calcined dolomite thermally stabilizes CaO. Synthetic dolomites with different MgO content are prepared by mechanical treatments and co-precipitation in order to find the optimal amount of MgO that improves the multicycle activity of CaO. Other materials in which the carbonation temperature can be increased, such as SrCO3 and BaCO3, are also studied, which would further increase the thermoelectric efficiency of CSP plants with thermochemical energy storage.
A relevant aspect of SOLACAL is that the results obtained will be transferred directly to the CSP-CaL demonstration plant that is being built in Seville within the H2020 SOCRATCES project, started in 2018 and coordinated by the University of Seville.
Development of light emitting devices based on nanostructured perovskite
01-01-2020 / 31-12-2022
Research Head: Hernán R. Míguez García
Financial Source: Junta de Andalucía
Code: P18-RT-2291 "Frontera"
Research Team: Juan Francisco Galisteo López, Mauricio E. Calvo Roggiani, Gabriel S. Lozano Barbero
The Nano-ABX LED project focuses on finding ways to solve the main challenges facing the field of perovskite-based light emission. These are the chemical and thermal instability of perovskites, as well as the difficulty of maintaining a high quantum efficiency regardless of the emission color, which makes it difficult to obtain both a varied color range and different shades of white (ie, different temperatures color).
The Nano-ABX LED project arises with the motivation to find solutions to these problems. Based on recent preliminary results of the Multifunctional Optical Materials Group, an attempt will be made to demonstrate that the integration of hybrid perovskite nanocrystals inside matrices with controlled porosity dramatically improves the environmental stability of these materials, an aspect that the group requesting this proposal has studied in depth, as well as it allows to increase the luminescent quantum efficiency at controlled emission wavelengths. In another aspect of the project, the increase in efficiency and performance (directionality, spectral control) of the devices will be explored through the integration of different photonic structures, taking as a starting point.
Formic acid as energy vector: feasability of hydrogen charge/discharge cycles
01-01-2020 / 31-12-2022
Research Head: Svetlana Ivanova / Miguel Angel Centeno
Financial Source: Junta de Andalucía
Code: P18-RT-3405
Research Team: María Isabel Domínguez Leal, Leidy Marcela Martínez Tejada
This project is part of the current trend for future technologies of Carbon dioxide Capture and Utilization (CCU). His interest lies in a direct use of atmospheric CO2 to store green hydrogen (produced with the help of renewable energies) as formic acid directly used as an energy vector. From an environmental point of view, the development of this technology would make possible the preservation of the CO2 footprint during the complete cycle of energy generation, storage and release, without generating more greenhouse gases. The possibility of storing hydrogen in this way would facilitate its transport and its use in diverse applications, both mobile and stationary. Indirectly, this technology would rationalize the storage of renewable energies, making them independent of climatic conditions. This project aims to study the feasibility of the technology based on the development of one unique stable and selective catalyst for both, hydrogen charge and discharge cycles (CO2 / HCOOH).
New nanostructured coatings for efficient absorption of solar radiation in concentrated devices
01-01-2020 / 31-03-2023
Research Head: Juan Carlos Sánchez López
Financial Source: Junta de Andalucia
Code: P18-RT-2641 "Frontera"
Research Team: T. Cristina Rojas Ruiz, Belinda Siguenza Carballo
The improvement of the materials employed in the devices used in the renewable energy sector will enable to increase the efficiency of these systems to become more competitive and profitable. The current project aims to develop new solar selective coatings able to operate at temperatures beyond the working temperature limits of the materials currently being used in concentrated solar systems (500ºC in vacuum- mid concentration; 800ºC in air –high concentration). The systems will be prepared in the form of multilayers using the novel technology of magnetron sputtering where the materials are evaporated by means of high energy pulses (HiPIMS - High Power Impulse Magnetron Sputtering). The developed materials should fulfill the optical requirements and thermal stability to withstand the high solar irradiance flux and working temperatures. This project will be carried out through the collaboration of two research groups belonging to the “Instituto de Ciencia de Materiales de Sevilla”, CSIC-ICMS (TEP958 group) and the “Plataforma Solar de Almería”, CIEMAT-PSA (TEP247 group). The ICMS-CSIC group will perform the design, preparation and characterization of the coatings. Meanwhile, the CIEMAT-PSA group will be in charge of designing the bench tests, validating the coatings in working conditions similar to the final application in terms of high incident solar flux and operation temperatures. Such tests will include both the determination of thermal and optical parameters in nominal operating conditions, as well as the thermal cycling at high frequency (thermal treatment and aging).
Smart thermochromic coatings for smart windows and environmental control (TOLERANCE)
01-01-2020 / 31-03-2023
Research Head: Angel Barranco Quero / Alberto Palmero Acebedo
Financial Source: Junta de Andalucia
Code: P18-RT-3480 "Frontera"
Research Team: Ana María Gómez Ramírez, Juan Ramón Sánchez Valencia, Victor J. Rico Gavira, Rafael Alvarez Molina, Francisco Yubero Valencia, Juan Pedro Espinós Manzorro, Ana Isabel Borrás Martos, Agustín R. González-Elipe
The International Energy Agency considers that the systematic use of autonomous procedures for environmental control is one of the best technological approaches to minimize the energy employed to cool down buildings and other urban structures (it represents more than 40% of the global energy use in developed countries, much above the use in transportation, for instance), thus reducing the environmental impact and improving human comfort. TOLERANCE aims at introducing and developing a technology based on thermochromic materials in Andalusia as a smart and autonomous element to control the penetration of solar radiation in buildings. This project focusses on various applications such as smart windows in buildings and urban furniture, improvement of sanitary water systems or environmental control in greenhouses. While at low temperatures, a thermochromic coating transmits most solar spectrum, it selectively filters out the infrared region of this spectrum at high temperatures. In this research, TOLERANCE proposes several R+D actions to grow thin films with composition VO2, a thermochromic oxide with transition temperature near room temperature, on glass and plastic by means of industrial scalable techniques, as well as its nanostructuration, doping and integration in multilayer systems to improve its features and multifunctional properties.
Development of catalysts and supports for CO2 neutral chemical energy storage processes based on liquid organic hydrogen carriers
1-1-2019 / 30-09-2022
Research Head: María Asunción Fernández Camacho
Financial Source: Ministerio de Ciencia, Innovación y Universidades
Code: RTI2018-093871-B-I00 - "Retos Investigación"
Research Team: María del Carmen Jiménez de Haro
TIle depletion of fossil fuels (in short and long term) and the global warming derived from greenhouse eHect are consequences of the extensive use of these fuels. It is therefore highly desirable to use and develop renewable energies and so eliminate our dependence on fossil tuels. This makes the storage of energy produced by renewable sources (which are ¡ntermittent) an important target. In previous projects we have been working in the study of nanomaterials and catalysts for the storage of hydrogen as a vector of energy transport and storage (H2 cycle). In this new project the research group propose to move into the implementatlon of the liquid organic hydrogen carriers (LOHC) as a promising way of comblning the C02 and de H2 cycles leading to a sustainable energy storage in a carbon neutral cycle.
Small organic molecules, IIke formic acid or methanol, can be used to store the H2 (and energy) coming from renewable sources. These alternative fuels can be combusted themselves or be used to generate H2 directly feeding a fuel cell.
Research will be conducted in this project to the implementation of two processes related to the LOHC technologies:
i) The selective low temperature decomposition of formic acid by heterogeneous catalysis to the on-demand production of carbon monoxide free hydrogen.
ii) The hydrogen production by reforming of alcohols (i.e. biomethanol) in heterogeneous photocatalytic processes.
Catalysis is playing the key role in the implementation of these Iwo processes. Therefore the main objectives and activities in the project are the rational design and preparation of catalysts and supports to study composition-structure-performance relationships for the two aboye mentioned processes. The innovative approach is the application of plasma assisted techniques, like the magnetron sputtering for
thin film growth, as well as plasma treatments of oxidation, reduction and etchlng for the development of nanostructured catalytic coatings and supported nanoparticles. Porous carbon foams supports and Pd based catalysts including Pd, Pd-C, Pd-B or Pd-Cu will be developed for the study of the formic acid decomposition reaction. Ti02-TiOx photocatalytic films with Pt (and/or gold) as co-catalysts will be
investlgated for the photo-reforming 01 methanol.
Multifunctional nanoparticles for luminescent, magnetic resonance and X-ray computed tomography bioimaging
1-1-2019 / 30-09-2022
Research Head: Manuel Ocaña Jurado / Ana Isabel Becerro Nieto
Financial Source: Ministerio de Ciencia e Innovación
Code: RTI2018-094426-B-I00 "Retos Investigación"
Research Team: Nuria O. Nuñez Alvarez
The project pursues the preparation of multifunctional nanoparticles (NPs) with improved properties and suitable characteristics (size, colloidal stability and toxicity) that can be used to get images of cells, tissues and organs by means of more than one bioimaging technique, thus providing complementary information essential for a more reliable medical diagnosis. Specifically, we shall study
bifunctional probes for both, luminescence and magnetic resonance (MRI) or luminescence and X-ray computed tomography (CT), and trifunctional probes that are useful for the three imaging techniques.Two types of luminescent probes will be addressed. On the one hand, luminescent NPs will be designed consisting of single matrices doped with lanthanide cations (Nd3+ or Er3+lYb3+ or Tm3+lYb3+), whose excitation and emission takes place in the near-infrared (NIR) region known as the biological window (650-1800 nm), in which radiation is not harmful to tissues and has a high penetration power. On the other hand, nanoprobes whose luminescence persists after ceasing the excitation will be also developed, thus avoiding the possible undesirable effects of the excitation radiation on the tissues. In the first case, our aim is to achieve greater chemical and thermal stability of the pro bes by selecting oxifluoride-type matrices, more stable than the
fluoride-type matrices proposed so far. In the second case, the aim of the project resides in the exploration of new synthetic routes to obtain nanoparticulated ZnGa204:Cr3+ and Y3AI2Ga3012:Ce3+,Cr3+,Nd3+, with uniform size and shape, which are essential for bioapplications. Regarding MRI technique, this project aims at developing NPs made up of Dy- and Ho-based oxifluorides, vanadates and phosphates in response to the need of new contrast agents that work at high magnetic fields, which are increasingly being used in clinics to improve image resolution. Finally, due to the high atomic number of the constituent elements of the selected probes, it is expected that they show a high X-ray attenuation capacity, being therefore also useful as CT contrast agents. The advantage of the NPs proposed in this research with respect to the CT CAs currently used in clinics is the longer circulation time of the former, which will allow decreasing considerably the dosage to be given to the patient. The project contemplates both the manufacture of optimised probes and the exploration of their applicability to the field of medical diagnosis by obtaining "in vivo" images in mice. The research team has long experience in the synthesis of rare earths-based inorganic NPs and has most of the necessary equipment for their characterisation. The participation in the work plan of researchers from other institutions, with long expertise on various aspects of the project, who have successfully collaborated with the research team, gives further support to the viability of the proposal.
Power-to-X processes for CO2 valorization in structured catalytic reactors (CO2-PTX)
1-1-2019 / 31-12-2021
Research Head: José Antonio Odriozola Gordón / Francisca Romero Sarria
Financial Source: Ministerio de Ciencia e Innovación
Code: RTI2018-096294-B-C33 "Retos Investigación"
Research Team: Luis F. Bobadilla Baladron, Maria Isabel Dominguez Leal, Anna Dimitrova Penkova, Lola de las Aguas Azancot Luque, Marta Romero Espinosa, Juan Carlos Navarro de Miguel
The main idea underlying the term "Power-to-X" is the storage of energy (preferably renewable) in the form of chemical products.
Thereafter, these products may be employed in energy-related applications or as platform chemicals. As a result, the Power-to-X (PTX) processes play a key role in increasing the penetration rate of renewables in the energy mix in line with European Unions long-term objective of reducing greenhouse gas (GHG) emissions by 80-95 % by 2050 when compared to 1990 levels. Production of hydrogen by water electrolysis is a mature and commercially available technology that can be used during periods of low demand for renewable energy.
On the other hand, CO2 is the only abundant carbon source within the EU and the combined use of renewable hydrogen and CO2 remarkably results in additional benefits in the PTX concept since CO2-associated GHG emissions is reintegrated in the value chain contributing to circular economy and decarbonization. This main idea drives CO2-PTX proposal. Specifically, our proposal aims to carry out the following reactions in structured catalytic reactors: CO2 hydrogenation to methane (also called methanation or Sabatier reaction), the reverse Water-Gas Shift reaction (CO2 activation and adjustment of the H2/CO ratio) and the direct synthesis of biofuels (dimethyl
ether and FTS) and acetic acid. This set of reactions provides remarkable challenges in key catalytic engineering aspects such as: i) development of suitable multifunctional structured catalysts; ii) management of the thermal effect of highly exothermic reactions; iii) control of the selectivity of multiple reactions in series through the joint action of the reaction temperature, the residence time and suitable catalyst formulation and reactor configuration. The know-how acquired by the consortium during previous projects (MAT2006-12386, ENE2009- 14522, ENE2012-37431 and ENE2015-66975) allows us to propose the use of structured catalysts and reactors as a very convenient way
of addressing that challenges. Heat and mass transfer rates intensification provided by metallic substrates-based structured systems as well as the flow patterns characteristic of open-cell foams are expected to play a determinant role in temperature and selectivity control. In this regard, several catalytic-wall reactor configurations as parallel-channels monoliths and open-cell foams will be considered, as well as other characteristics that directly affect the transport properties of the structured systems (monolith cell density, pore density of foams, metal alloy used as substrate and catalyst layer thickness).
To be closed to practical applications it will be also considered within the CO2-PTX project the valorization of CO2 present in dilute streams, typically flue gases. This entails additional challenges arising from the low concentration of CO2, high volumetric flow rates and negative effects of other components (H2O, SOx, etc.) on the catalytic activity and stability. Improved catalyst formulations as well as sorption-enhanced CO2 conversion strategies in structured reactors will be investigated.
Overall, the project is organized as a series of transversal tasks for which each group contributes with his main field of specialization and vertical tasks associated to a more intense dedication of each group to one or more of the processes investigated.
Processing and characterization of ceramic composites with two-dimensional laminar nanomaterials
01-01-2019 / 31-12-2022
Research Head: Angela Gallardo López (UEI) / Rosalía Poyato Galán
Financial Source: Ministerio de Ciencia, Innovación y Universidades
Code: PGC2018-101377-B-I00 "Generación de Conocimiento"
Research Team: Felipe Gutiérrez Mora (UEI), Ana Morales Rodríguez (UEI), Antonio Muñoz Bernabé (UEI), Rocío del Carmen Moriche Tirado (UEI)
Two-dimensional nanomaterials are being increasingly used as fillers in ceramic composites in an effort to overcome the inherent fragility of ceramics and to provide them with new functionalities. There are open issues in the field of these composites regarding their strength and fracture toughness mechanisms, crack growth kinetics, tribological behavior, role of interfacial phases or suitability for electrical discharge machining, among others. Although graphene nanosheets (GNS) are excellent fillers, inorganic graphene analogues could extend the range of applicability of graphene ceramic composites. The use of boron nitride nanosheets (BNNS) as fillers in ceramic composites is promising and practically unexplored.
This proposal outlines a systematic study of composites intended for use in structural and functional applications, with two different ceramic matrices from the yttria-stabilized zirconia system incorporating two different 2D laminar nanomaterials -graphene or boron nitride nanosheets-, to deepen in the understanding of their mechanical and electrical behavior. To that end, composites with 3 mol% yttria tetragonal zirconia and 8 mol% yttria cubic zirconia matrices will be fabricated, pursuing an optimum microstructure with a homogeneous distribution of the 2D nanomaterials throughout both ceramic matrices. On the one hand, ceramic composites with graphene nanosheets will be investigated in depth to complete the gaps in the current knowledge of these materials. The distribution, size and structural integrity of the GNS will be characterized by X-ray diffraction, scanning electron microscopy and Raman spectroscopy while the interfaces between the GNS and the matrix will be characterized by transmission electron microscopy. The strength, failure resistance, reinforcement mechanisms and crack growth kinetics of these composites will be thoroughly examined, and the best combination of processing route and GNS content in terms of reinforcement will be established. Electrical conductivity measurements of composites with different GNS contents will be carried out at room temperature and the response to electrical discharge machining of the electrically conductive composites will be evaluated. Conductivity measurements will be carried out also as a function of temperature in order to describe the possible variations of conduction type when increasing the GNS content. On the other hand, ceramic composites with boron nitride nanosheets will be investigated in order to get a first approach to the understanding of this system. For this purpose, after the synthesis of the BN nanosheets using a mixed-solvent strategy for liquid exfoliation of BNNS from h-BN powder, composites with different contents of BNNS will be prepared using wet powder processing techniques. The microstructural characterization of the spark plasma sintered composites will be carried out by scanning and transmission electron microscopy, X-ray diffraction and Raman spectroscopy. Mechanical properties as hardness, flexural strength and wear resistance will be studied at room temperature, whereas deformation tests at high temperatures will be also performed. The electrical conductivity as a function of temperature will be analyzed in order to clarify the effect of incorporating an insulating second phase at the grain boundaries on the electrical performance of an ionic conductor.
Unraveling the genetic and biophysical basis of tomato fruit cuticle formation
01-01-2019 / 30-06-2022
Research Head: Eva María Domínguez Carmona (IHSM) / Rafael Muñoz Fernández (IHSM)
Financial Source: Ministerio de Ciencia e Innovación
Code: RTI2018-094277-B-C22 "Retos de la Sociedad"
Research Team: José Jesús Benítez Jiménez, Manuel León Camacho (IG)
Waxes and phenolics are minor compounds of the tomato fruit cuticle that nevertheless play a significant role in determining several aspects related to fruit quality. Phenolics have been demonstrated to modulate fruit color appearance and cuticles stiffness, thus determining fruit sensitivity to cracking during ripening. They are not, however, the only contributors to the mechanical properties of the cuticle. In previous projects we located and validated five QTLs related to the amount of cuticle phenolics, identification of the genes responsible for these genomic regions will improve our understanding of this trait and how to modulate it in order to generate commercial lines with desirable combinations of fruit color and mechanical resistance. In this sense, a QTL analysis of the mechanical and thermal properties of the cuticle will be the first known approach to the genetic basis of a biophysical property. Cuticular waxes, on the other hand, are the major barrier to water permeability and, in this sense, regulate the hydric status of fruits during harvesting, post-harvest and storage. A preliminary analysis of wax content in the wild species related to the cultivated tomato, revealed two red-fruited species of potential interest for developing new varieties with tolerance to dehydrating environments. The analysis of water permeability and wax quality of the cuticle in this two species will be the first step towards this ultimate goal.
Verification of the existence of macroscale repulsive Casimir forces in suspend self-standing films
1-11-2018 / 30-04-2021
Research Head: Hernán Ruy Míguez García
Financial Source: Ministerio de Ciencia e Innovación
Code: FIS2017-91018-EXP "Explora"
The ultimate goal of the VERSUS project is the first observation of repulsive Casimir-Lifshitz forces in macroscopic plane-parallel systems. To this end, it will focus on the design, fabrication, and characterization of optical materials that allow controlling the intensity and nature of the Casimir-Lifshitz force, so that levation phenomena can be observed and characterized due to the balance between the latter and gravity force. This radically new approcah makes use of optical spectroscopic techniques (based on optical interferometry between the partially reflected and transmitted light at the interfaces of the plane-parallel system) for characterizing the equilibrium distance at which the system levitates over a substrate. According to very recent results attained by the applicant group, it is possible to find materials whose optical constants and densities are such that when they are immersed in a fluid they can levitate over a substrate as a result of the aforementioned force balance. Our group has recently demonstrated theoretically that there is a number of materials that prepared in this films (<1 micrometer) can levitate several tens or hundreds of nanometers over a carefully selected substrate. Specifically, thin layers made of teflon, polystyrene or silicon dioxide immersed in glycorel are expected to levitate over a silicon wafer, being possible to tune the equilibrium distances at which such layers will be suspended through their thicknesses and temperature of the system. The devised selft-standing thin films (in single layers or multilayer arrangements) must be compact, mechanically stable, of smooth surfaces, of controlled thickness, and chemically compatible with the fluid in which they are immersed. The macroscopic observation of repulsive Casimir-Lifshitz forces, never reported before, through optical spectroscopic measurements would constitute an unprecedented milestone in the field of fundamental matter interactions.
Advanced optical materials for more efficient optoelectronic devices
01-01-2018 / 30-09-2021
Research Head: Hernán Ruy Míguez García / Mauricio E. Calvo Roggiani
Financial Source: Ministerio de Ciencia e Innovación
Code: MAT2017-88584-R "Retos de la Sociedad"
Research Team: Gabriel S. Lozano Barbero, Juan Galisteo López
The MODO project is focused on the optimization of the optical design of optoelectronic devices, be they photovoltaic or light emitting ones, with the aim of increasing their efficiency or endow them with new functionalities. The hypothesis on which it is based is that this goal can be reached by means of the integration of optical materials that allow controlling the radiation-matter interaction in the absorbing or optically active layers of the device. The strategy herein proposed is based on the sequential realization of design, preparation, characterization and integration of devices of diverse photonic structures (photonic crystals, metallic particles, disordered optical media, corrugated surfaces) employing mainly solution processing techniques fully compatible with those used to fabricate the targeted devices. Optoelectronic technology based on perovskites has attracted a great deal of interest in the last years as a result of the high solar to electric power conversion efficiency, above 20%, that have been reached in a relatively short time compared to other photovoltaic technologies. At the same tiem, they present high photoemission quantum yields in the green and the red, which make them also good candidates as color converter layers for LEDs. However, these expectations are partially threatened by both the stability problems and potentially toxic environmental effects they present. It is one of the main goals of this project to propose solutions to specific drawbacks present in the optoelectronic technology based on hybrid perovskites through the implementation of optical designs that gives rise to a reduction ot both the amount of material employed as well as the exposure to environments that typically degrade them. We seek to deepen our understanding of phenomena that give rise to the photoinduced degradation of these materials when exposed to diverse environments, which will allow us to propose specific solutions to develop more stable and efficient perovskite layers. Simultaneously, concepts based on the strict control over the local density of photon states and oriented to the directional amplification of luminescence at selcted spectral ranges will be applied to light emitting devices based on semiconductor nanocrystals as well as to photo- and electro-luminescent organic compunds. Full control over the excited state decay dynamics over large areas and observation of laser emission will also be sought after. In all cases, the energy efficiency of the targeted devices has not been optimized before from the point of view ot the optical design.
The proposal is included in the framework of the Societal Challenge called "Secure, clean and efficient energy" and aims to develop photonic technology using nanotechnology tools and in the advanced materials field, all identified as Key Enabling Technologies KETs in the Spanish Strategy on Science and Technology, aligned with the European Program H2020.
Biomass valorization and sustainable energy production over (photo)catalysts and structured reactors based on carbonaceous materials
01-01-2018 / 30-09-2021
Research Head: Miguel Angel Centeno Gallego / Svetlana Ivanova
Financial Source: Ministerio de Ciencia e Innovación
Code: ENE2017-82451-C3-3-R "Retos de la Sociedad"
Research Team: Carlos López Cartes, Leidy Marcela Martínez Tejada, María Isabel Domínguez Leal, Regla Ayala Espinar
The main goal of ENERCARB, project coordinated among the U. of Zaragoza, the ICMS and the U. of Cádiz, is the development of multifunctional and structured catalysts based on carbonaceous catalytic materials of biomorphic and/or graphenic-graphitic character. These materials must be active, selective and stable in catalytic reactions related to i) the production and use of chemicals derived from lignocellulosic biomass, i.e. 5-HMF, levulinic acid, FDCA and g-valerolactone; ii) to sustainable energy vector production (H2), and iii) to chemical and photochemical utilization of CO2 (CO2 hydrogenation), biogas decomposition, photo-reforming of bio-alcohols) using H2 of renewable origin (“water splitting”). This project tries to improve currently implemented processes for energy production, and to propose other more innovative processes, such as use of sunlight, undoubtedly called to play an important role in this field. In fact, the use of solar energy would make more energy-efficient, the CO2 methanation reaction by using H2 of (photo)renewable origin produced by "water splitting". ENERCARB also intends to generatre high added value products by bio-refinery processes, as alternative to currently obtained chemicals from fossil sources. A set of carbonaceous solids with tunned structural properties (meso/micro hierarchical porosity), hydrophilicity-hydrophobicity, chemical functionalities, surface composition, etc., will be designed ad hoc for each of the reactions considered by the different subprojects. The implementation of continuous processes through the use of structured reactors is the next logical step to increase the efficiency of the the proposed proceses. The development and use of structured catalytic systems increases the viability and intensifies the processes, and therefore leads to higher energy and environmental efficiency. The complimentary nature of the three participating groups opens the possibility of addressing all these objectives in one single project. It will allow the application of different emerging methodologies for the synthesis of new carbonaceous materials, such as biomorphic mineralization, the expansion-functionalization of graphite intercalation compounds, special graphites (e.g. graphite nanolayers or nanoflakes), use of inorganic templates for the generation of mesoporous carbons, and also its advanced functionalization and its application in processes of high impact in the area of energy, chemical and environmental technologies
Development of new nanostructured materials for methane valorization to C2-C4 olefins
1-1-2018 / 31-12-2020
Research Head: Alfonso Caballero Martínez / Gerardo Colón Ibáñez
Financial Source: Ministerio de Ciencia, Innovación y Universidades
Code: ENE2017-88818-C2-1-R "Retos de la Sociedad"
Research Team: Rosa Pereñiguez Rodríguez, Francisco Jesús Platero Moreno, Angeles Maria López Martín, Juan Pedro Holgado Vázquez
In the present project the preparation of a set of materials, including some with perovskite structure (Fe, Co, Mn, Cu and Bi in positions B; Ca, Mg, Ce and La in positions A), and the study of its application in different processes of heterogeneous catalysis and adsorption of pollutants has been proposed. For this purpose, a number of recently described preparation techniques will be used to obtain high surface specific and controlled nanostructure systems. In this way, and combining the metals in positions A and B to act both as promoters and precursors of metal alloys in the reduced systems, systems with very varied and versatile properties will be obtained.
Thus, we will study its catalytic properties in processes of great interest for the valorization of methane, the main component of natural gas and one of the most abundant energy sources today. In particular, and together with systems supported on mesoporous materials and others, the activity of nickel perovskites for the dry methane reforming reaction will be studied first in order to obtain synthesis gas. The aim will be to obtain active and above all stable systems in the face of the usual deactivation phenomena by deposition of coke. Secondly, systems based mainly on Fe and Co for the Fisher-Tropsch reaction to C2-C4 olefins will be studied, products of great economic interest as precursors to a large number of other high added value products.
Integration of the Ca-looping process in concentrated solar power plants for thermochemical energy storage
01-01-2018 / 30-09-2022
Research Head: Luis A. Pérez Maqueda
Financial Source: Ministerio de Ciencia e Innovación
Code: CTQ2017-83602-C2-1-R "Retos de la Sociedad"
Research Team: Pedro Enrique Sánchez Jiménez, María Jesús Diánez Millán
The proposal deals with the general social challenge of finding new cheap and environmentally friendly energy storage technologies to overcome the intermittency of energy generation from renewable sources. Particularly, in this project we propose integrating Ca-looping technology within a thermosolar concentration plant. Ca-Looping technology was originally proposed for CO2 capture and it is based on cycled carbonation-calcination of calcium oxide-calcium carbonate. Our research group has been working on this technology for several years with the objective of understanding the deactivation mechanisms as the number of cycles increases. Thus, we have studied the kinetic mechanisms of these processes and the microstructural changes that takes place during cycling. In a coordinated project that is about to finish this year (SOLARTEQH, Retos 2014) where we already proposed the integration of Ca-Looping for thermosolar energy storage. This project was the basis of a H2020 proposal (SOCRATCES) that has been recently approved and that will start by the beginning of 2018. The project CALSOLAR is a step forward in the integration to increase the efficiency of the plant. Subproject 1 will coordinate the new project. Moreover, subproject 1 will select, prepare and characterize all compounds investigated in the project. We will work with mining companies that will provide the raw materials (mainly limestone and dolomite) with different purities and crystallinity. Composite materials with nanostructured silica obtained from rice husk (provided by rice mills from the Guadalquivir area) will be prepared. Compounds obtained from steel slags (supplied by nearby steel mills) rich in calcium will be prepared. Within subproject 1, a new thermogravimetric instrument to perform thermal storage cycles under realistic conditions will be designed and constructed in our laboratories. This instrument should work under different controlled CO2 pressures and under superheated steam. The kinetic
mechanisms of carbonation and decarbonation and the microstructural changes will be investigated during cycling. The working team is experienced in the tasks of the project while some additional external scientists will participate. Thus, two foreign professors with solid backgrounds in solid-gas reactions and high resolution TEM are collaborating with us. Moreover, an industrial scientist from Abengoa with a very broad experience in thermal storage and thermosolar power plants is also included in the team. Both subprojects will work in a coordinated way with the aim of setting the optimum conditions for the final application. Finally, the results of the project will be directly applied to the pilot plant constructed within the H2020 SOCRATCES project.
SOlar Calcium-looping integRAtion for Thermo-Chemical Energy Storage
01-01-2018 / 30-09-2021
Research Head: Luis A. Pérez Maqueda
Financial Source: Unión Europea
Code: H2020-ENERGY/0373 "Research & Innovation Action"
Research Team: María Jesús Diánez Millán, Pedro Enrique Sánchez Jiménez
Energy storage is one of the the greatest challenges for a short-term deeper penetration of Concentrating Solar Power (CSP) plants, which are usually characterized by the intermittency of power production. The Ca-Looping (CaL) process based upon the reversible carbonation/calcination of CaO is one of the most promising technologies for thermochemical energy storage (TCES). The wide availability of natural limestone (almost pure CaCO3) and its low price (<10€/ton) are key factors for the feasibility of the CaL process.
SOCRATCES is aimed at demonstrating the feasibility of the CSP-CaL integration by erecting a pilot-scale plant that uses cheap, abundant and non-toxic materials as well as mature technologies used in the industry, such as fluidized bed reactor, cyclones or gas-solid heat exchangers.
SOCRATCES global objective is to develop a prototype that will reduce the core risks of scaling up the technology and solve challenges; further understanding and optimise the operating efficiencies that could be obtained; with the longer-term goal of enabling highly competitive and sustainable CSP plants.
Rational design of highly effective photocatalysts with atomic-level control
02-10-2017 / 31-12-2020
Research Head: Gerardo Colón Ibañez
Financial Source: Ministerio de Economía y Competitividad. Unión Europea
Code: RATOCAT (project4076)
Research Team: Alfonso Caballero Martínez, Angeles Martín
Using the sun’s energy to generate hydrogen from water is probably the cleanest and most sustainable source of fuel that we can envisage. Unfortunately, catalysts that do this are currently too expensive to be commercially viable. The RATOCAT project aims to develop improved photocatalyst materials, along with the processes for their production. The catalytic performance of cheap TiO2 and C3N4 powders will be improved by tailoring their surface with nanostructured oxides as co-catalysts of highly-controlled composition, nanoarchitecture, size and chemical state. First principles simulations will be used to design the optimum nanostructures, which will then be deposited onto powders with the required precision using atomic layer deposition, again supported by simulation. Lab-scale tests of photocatalytic activity will provide feedback for the optimisation of the material and process, before the most promising materials are tested in the field on both pure water and wastewater.
Nanophosphor-based photonic materials for next generation light-emitting devices NANOPHOM
01-04-2017 / 31-03-2023
Research Head: Gabriel S. Lozano Barbero
Financial Source: Unión Europea
Code: H2020-ERC-STG/0259 STARTING GRANT
Energy-efficient and environmentally friendly light sources are an essential part of the global strategy to reduce the worldwide electricity consumption. Light-emitting diodes (LEDs) emerge as a key alternative to conventional lighting, due to their high power-conversion efficiency, long lifetime, fast switching, robustness, and compact size. Nonetheless, their implementation in the consumer electronic industry is hampered by the limited control over brightness, colour quality and directionality of LED emission that conventional optical elements relying on geometrical optics provide.
This project exploits new ways of controlling the emission characteristics of nanophosphors, surpassing the limits imposed by conventional optics, through the use of nanophotonic concepts. The development of reliable and scalable nanophosphor-based photonic materials will allow ultimate spectral and angular control over the light emission properties, addressing the critical shortcomings of current LEDs. The new optical design of these devices will be based on multilayers, surface textures and nano-scatterers of controlled composition, size and shape, to attain large-area materials possessing photonic properties that will enable a precise management of the visible radiation.
Nanophom will significantly advance our comprehension of fundamental phenomena like the formation of photonic modes in complex optical media to which light can couple, as well as advancing the state of the art of high-efficiency solid-state lighting devices.
Nanostructured multilayered architectures for the development of optofluidic responsive devices, smart labels, and advanced surface functionalization (NANOFLOW)
30-12-2016 / 29-06-2020
Research Head: Angel Barranco Quero / Francisco Yubero Valencia
Financial Source: Agencia Estatal de Investigación (AEI) y Fondo Europeo de Desarrollo Regional (FEDER)
Code: MAT2016-79866-R "Retos de la Sociedad"
Research Team: Agustín R. González-Elipe, José Cotrino Bautista, Juan Pedro Espinós Manzorro, Fabián Frutos (US), Ana I. Borrás Martos, Alberto Palmero Acebedo, Victor Rico Gavira, Ricardo Molina (IQAC-CSIC), Fernando Lahoz (ULL), Xerman de la Fuente (ICMA-CSIC), Jesús Cuevas (US), M. Fe Laguna (UPM), Antonio Rodero (UCO), M. Carmen García (UCO)
NANOFlow is a multidisciplinary Project that aims the development of novel optofluidics sensing devices integrating advanced multifunctional nanostructured materials. The project is solidly grounded in the research group experience in the synthesis of nanoestructured functional thin films, advance surface treatments and development of planar photonic structures The main objective of the project is to combine and integrate the available synthetic and processing methodologies in the fabrication of optofluidic components capable of modifying their physical behavior when they are exposed to liquids. The integration of these optofluidic components together with accessory technologies based on new principles of photonic detection, large surface area microplasmas discharge as light sources or flexible substrates for the fabrication of sensing tags define an ambitious landscape of applications that will be explored in the project. Besides, the modeling of thin film growth in combination with advanced deposition diagnosis methodologies will be combined to adjust the thin film deposition processes to the desired functionalities.Therefore, NANOFlow aims to cover all the scientific-technological chain from the materials development to the final applications including advanced characterization, flexible synthetic routes, alternative low-cost and high throughput process (e.g. atmospheric plasma synthesis), device integration and testing of devices in real conditions.
The NANOFlow research activities will culminate in the development of three innovative devices, namely smart labels for sensing, traceability and anticounterfeiting applications (e.g. smart labels incorporated in food-packaging), a versatile optofluidic multisensing device and an optofluidic photocatalytic cleaning system that will integrate a large area microplasma source, liquid actuated UV/Visible optical switches and a photocatalytic nanostructured surface. All of these devices will operate under the basis of an optofluidic actuation and/or response and are designed to present clear potentialities for direct application in liquid sensing, manipulation and monitoring.
The NANOFlow research activities in the different work-packages and, particularly, the final devices are intended to have a direct impact in the Theme 2 (Seguridad and Calidad Alimentaria) of the “RETOS” defined in the call covering this project proposal.. Besides, some of the activities proposed, in particular the third device are also connected with the Theme 3 (Energía segura eficiente y limpia) of the call. It is very interesting to stress that these activities are of particular relevance in the geographical context of Andalucia where Agriculture, Food production and Energy are three of the most relevant strategic sectors.
Bioceramic Materials for New Biomass Domestic Bolier Concept based on Porous Combustion for a Wide Biomass/Residues Feedstock
30-12-2016 / 31-12-2020
Research Head: Joaquín Ramírez Rico
Financial Source: Ministerio de Economía y Competitividad
Code: MAT2016-76526-R "Retos de la Sociedad"
Research Team: Julián Martínez Fernández, Manuel Jiménez Melendo
EU generates more than five tons of waste per person every year and about 60 % is organic waste. Current biomass domestic boiler technology does not allow the use of these residues with high efficiency, ultra-low emissions and high reliability operation. The main objective of this proposal is the development of a new concept of biomass domestic boiler technology able to combine these characteristics for operation with multiple biomass/residues blends. It is based on the integration of novel bioceramic porous materials matrices in combustion chamber and gases pathflow with functions as microporous combustors, particles filters and heat accumulators. These functions are simultaneous depending on the region of the boiler. Matrices of bioceramic materials are developed from wood precursors to obtain SiC elements through a process patented by the University of Seville. It uses local raw material, and produces parts with tailor made microstructure/properties, adequate for high temperature and reactive operation. Products with complex geometries can be obtained at relatively low cost compared with other materials of similar chemical and mechanical properties. The integration of components based on these materials allows new designs of biomass boilers with high control of combustion, temperature and particle emission. It avoids ash sintering and melting, acting on the formation and evolution mechanisms of ash and dioxins and activating the complete oxidation of CO and soots. The new concept allows the operation to a wider biomass/residues feedstock with low emissions and low maintenance even with fuels with high ash content, produced from many residues, solving main challenges for their extended use and increasing the European fuel resources for domestic heating. Domestic heating in Europe consumes 30% of the total energy. The proposal includes prototypes development, fuel supply characteristics and preparation (geometry, compactness, composition, etc.) and combustion products management. Biomass/residues blends from agriculture, forestry, olive oil industry among others will be tested both in laboratory .
Super-IcePhobic Surfaces to Prevent Ice Formation on Aircraft
01-02-2016 / 31-01-2019
Research Head: Agustín R. González-Elipe
Financial Source: Union Europea
Code: H2020-TRANSPORT/0149
The accretion of ice represents a severe problem for aircraft, as the presence of even a scarcely visible layer can severely limit the function of wings, propellers, windshields, antennas, vents, intakes and cowlings. The PHOBIC2ICE Project aims at developing technologies and predictive simulation tools for avoiding or mitigating this phenomenon.
The PHOBIC2ICE project, by applying an innovative approach to simulation and modelling, will enable the design and fabrication of icephobic surfaces with improved functionalities. Several types of polymeric, metallic and hybrid coatings using different deposition methods will be developed. Laser treated and anodized surfaces will be prepared. Consequently, the Project focuses on collecting fundamental knowledge of phenomena associated with icephobicity issues. This knowledge will give better understanding of the ice accretion process on different coatings and modified surfaces. Certified research infrastructure (ice wind tunnel) and flight tests planned will aid in developing comprehensive solutions to address ice formation issue and will raise the Project’s innovation level.
The proposed solution will be environment-friendly, will contribute to the reduction of energy consumption, and will help eliminate the need for frequent on-ground de-icing procedures. This in turn will contribute to the reduction of cost, pollution and flight delay.
A full plasma and vacuum integrated process for the synthesis of high efficiency planar and 1D conformal perovskite solar cells
01-01-2016 / 31-12-2017
Research Head: Angel Barranco Quero
Financial Source: Union Europea
Code: EU144338_01 Marie Curie Actions
Research Team: Juan Ramón Sánchez Valencia
Photovoltaic or solar cells (SC) devices –that transform light into electricity- have been extensively studied in the last decades since they represent a promising way to exploit the sun energy. Currently, perovskite-based solar cells(SC) are receiving increasing attention due to their low cost and high efficiency. They are very promising as an alternative for the existing ones, but still need to advance to reach higher efficiency and durability and require synthesis methods compatible with the industrial production of CMOS devices at wafer scale. These recent SC are mostly fabricated via wet methods in planar architecture. Inherent to the nature of the wet approaches, usually appear several drawbacks as contaminations and chemical reactions on the interfaces that might result deterioration of the SC performance.
PlasmaPerovSol main objective is the fabrication of a complete perovskite solar cell device by a full plasma and vacuum integrated process carried out under the premises of the “one reactor concept”. Thus, the different components of the solar cell will be deposited sequentially within a vacuum reactor avoiding exposition of the materials and interfaces to air or solvents. The technology developed by the hosting group combine vacuum deposition assisted by plasma that permits the fabrication of conformal layers over a large variety of templates. This approach is also proposed here to fabricate conformal multilayers over 1D scaffold that will demonstrate the advantages of 1D-SC. Plasma and vacuum processes present as advantage the high purity and stoichiometric control on the deposition within an ample range of materials compositions. The synthesis approach is compatible with large scale industrial production and allows the fabrication of SC on processable and flexible substrates. At the same time, the low temperatures used make the approach compatible with current CMOS technology and by using masks permits their integration on preformed devices.http://cordis.europa.eu/project/rcn/196104_es.html
Boron carbide and titanium nitride-based nanostructured ceramics for structural applications
01-01-2016 / 31-12-2020
Research Head: Diego Gómez García / Arturo Domínguez Rodríguez
Financial Source: Ministerio de Economía y Competitividad
Code: MAT2015-71411-R
Research Team: Francisco L. Cumbreras Hernández, Felipe Gutíerrez Mora, Ana Morales Rodríguez
Boron carbide and titanium nitride are among the most promising ceramic materials nowadays. In the first case, this is due to the outstandng mechanical properties (it is the third hardest material in nature) and its high resistance to chemical attack. In the case of Titanium nitride, its remarkable optical properties and electrical conductivity makes this a potential material for electronic devices. In both cases, sintering is a challenging issue due to the low diffusitivity. In this project, sintering of these materials by spark plasma sintering will be studied and the conditions for nanostructuration will be determined. Preliminary results show that average grain sizes as low as 100 nm can be achieved. In a second stage, plasticity will be studied. A previous model developed by the authors show that twinning is a key ingredient as a driving force of plasticity of boron carbide. The case of titanium nitride is mostly exciting because the stacking fault energy is the lowest ever known and it can make twinnin very favoured. The comparison between these two systems can be a clue about the basic mechanism for hardening in these ceramic materials.
Development of photo-functional materials for environmental applications
01-01-2016 / 31-12-2018
Research Head: José Antonio Navío Santos
Financial Source: Ministerio de Economía y Competitividad
Code: CTQ2015-64664-C2-2-P
Research Team: María del Carmen Hidalgo López, Manuel Macías Azaña
Heterogeneous photocatalysis is an advanced oxidation process which has been the subject of a huge amount of studies related to gas and water purification. Most of these studies have been performed for the treatment of water mainly by using the TiO2-based materials and more recently, although in a clear minority, by using other inorganic oxides binary, ternary and quaternary, predominating in all cases, the studies of the latter materials for water treatment. In terms of the photocatalyst, which is responsible of the efficiency of the photocatalytic processse, in the last decade have been developed numerous and varied methods of synthesis that have mainly been tested on processes of degradation in aqueous phase. However, few studies have been conducted with mixed oxides (binary, binary-coupled, ternary or quaternary) and less in gas phase.
Based on the above considerations and given the long and recognized experience that members of this Subproject# 2 have in the field of synthesis and characterization of photo-functional materials ( UV and UV/Vis), an due also due to the small number of photocatalytic studies in the gas phase , most of them by studying a single component, the work arises in this Subproject # 2 is the development of photo-functional materials that lead to materials based, not only on TiO2 with improved properties but other materials based on this oxide and other binary inorganic oxides, those obtained by coupling of binary oxides and ternary, which are obtained by processes of different synthesis to those already reported in the literature, and whose photoactivity will be evaluated by the group of Subproject # 1, without discarding a prior testing photocatalytic activity in water by the group of Sub-group # 2.
Among the materials that are to be synthesized in the Subproject # 2 ( by using non-hydrothermal, hydrothermal and sol-gel methods) are contemplated: binary oxides (TiO2, ZnO, WO3, Fe2O3, Bi2O3, Ta2O5, La2O3), coupled binary oxides (TiO2-WO3, TiO2-ZnO, TiO2-ZnO2, TiO2-Ta2O5, TiO2-La2O3, ZnO-Fe2O3 y ZnO2-Fe2O3), ternary oxides (Bi2WO6, Bi2WO6-ZnO, Bi2WO6-ZnO2, Bi2WO6-Fe2O3, Bi2Ti2O7, ZnWO4,La2Ti2O7) studying the photo-deposition of single metals (Pt, Ag, Au) on those prepared systems that exhibit significant photocatalytic activity (Semiconductor /Metal). Best evaluated systems will be forwarded to the Subprojet 1 for the feasibility study on the photocatalytic removal of NOx, VOCs, CO, CO2 and SO2 present in gaseous emissions..
Development of supported catalysts on porous structures for hydrogen generation and catalytic combustion applications in the framework of renewable energies
01-01-2016 / 31-12-2018
Research Head: Asunción Fernández Camacho
Financial Source: Ministerio de Economía y Competitividad
Code: CTQ2015-65918-R
Research Team: Asunción Fernández, Mª Carmen Jiménez de Haro, Vanda Godinho, Gisela Arzac, Dirk Hufschmidt, Rocio García
The depletion of fossil fuels (in a short and long term) and the global warming derived from greenhouse effect are consequences of the extensive use of these fuels. In this context, hydrogen appears as an attractive, clean and abundant energy carrier in the context of a wider use of clean and removable energies. For the implementation of the “hydrogen economy” many technological challenges regarding hydrogen production (free from CO2), transport, storage (in a safe manner) and combustion (to produce heat or electricity) should be met first. New research will be conducted in this project on the basis of our previous results regarding the study of complex hydrides for hydrogen storage and the development of catalysts and processes for hydrogen generation and use in portable applications. In particular, new catalysts will be developed on porous structures such as polymeric, metallic and ceramic membranes and/or foams with high actual interest. Catalysts will we developed and studied for hydrogen generation and combustion reactions according to the following research lines:
1) Development of new materials (catalysts and supports) with a high added value of the complete system catalyst + support. Porous Ni and SiC foams together with PTFE membranes will be selected as supports for the studies. The main objective is to design new catalysts on technologically interesting supports such as separating membranes, electrolytes, electrodes and/or hydrogen combustors. These new catalysts will be developed following the objective of reducing the amount of noble metals by combining or replacing with another non-noble metals (e.g. Pt-Cu and Ni-Fe) and/or with metalloids (e.g carbides, borides, etc). Wet impregnation methods will be used and special emphasis will be put on the use of the PVD methodology (magnetron sputtering) recently employed in our laboratory for the fabrication of Co thin films with very good results. The latter methodology opens a highly interesting research field because permits to tune microstructure and composition (i.e. Co, Co-B, Co-C) on demand.
2) Characterization of the prepared materials from a microstructural and chemical point of view. Modern nanoscopies will play a key role in the characterization, comprehension and further improvement of these highly nanostructured catalysts.
3) Catalytic studies on the prepared materials will be carried out in three catalytic tests: i) the hydrogen generation through hydrolysis reactions, ii) the photocatalytic water splitting, and iii) the catalytic hydrogen combustion. These reactions are of high interest in the context of the hydrogen economy.
--The interaction of these three research lines as proposed in this project will permit to achieve basic knowledge on the rational design of nanocatalysts supported on porous materials. Structure-composition-activity relationships will be established through catalytic and photo-catalytic studies in combination with characterization techniques based on high resolution analytical TEM and additional spectroscopic techniques.
Genetic basis of the composition and biophysical properties of tomato fruit cuticle: exploiting natural variability
01-01-2016 / 31-12-2018
Research Head: Fafael Fernández Muñoz (IHSM)
Financial Source: Ministerio de Economía y Competitividad
Code: AGL2015-65246-R
Research Team: José Jesús Benítez, Fernando Gallardo Alba (UMA), Antonio Heredia Bayona (IHSM)
Production of fruits with high quality and added value is currently an important challenge in agriculture. The cuticle that covers the outer epidermal cell walls plays a significant role in tomato fruit quality mainly in its external appearance (color, glossiness, texture, uniformity), in the occurrence of disorders of great economical importance such as fruit cracking, and also in the maintanance of fruit water status during postharvest. In previous projects (AGL2006-12494, AGL2009-12134 and AGL2012-32613) of which this can be considered a continuation, the important role of cuticle on fruit cracking and how changes in cuticle biomechanical properties affect cracking were highlighted. Moreover, it was shown that cuticle flavonoids, which are involved in the color of ripen fruits, play an important role in the regulation of cuticle synthesis and water permeability. Both a recombinant inbred (RIL) and an introgression line (IL) S. lycopersicum x S. pimpinellifolium populations will be used for validation and identification of QTLs and candidate genes involved in the deposition of different cuticle components (waxes, cutin, flavonoids, polysaccharides) and also for identification of QTL/genomic regions associated to unstudied cuticle traits such as thickness and density. This multidisciplinary approach, that includes cuticle biophysical analyses, will allow designing tomato cultivars with adequate biomechanical and hydrodinamical properties to reduce cracking, maintaining fruit water status during postharvest and avoiding skin traits undesirable for consumers. A collection of wild tomato species accessions will be studied and will provide insights in cuticle evolution within the Lycopersicon taxon. This evolutionary study could reveal different combinations of components and structures that will be useful to increase the current cuticle variability for future breeding programs.
High temperature energy application coatings
01-01-2016 / 31-12-2018
Research Head: Juan Carlos Sánchez López
Financial Source: Ministerio de Economía y Competitividad
Code: MAT2015-65539-P
Research Team: Iñigo Braceras Izaguirre (INASMET), Teresa Cristina Rojas Ruiz, Maria Belinda Sigüenza Carballo
The protection of surfaces from thermal, wear and oxidation phenomena has reached a substantial progress by developing new materials and coatings with improved properties as extreme hardness, low friction and wear rates, increased thermal and oxidation resistance. These improvements suppose a huge energy-saving and cost reduction due to the increased life-time of mechanical components without needs of replacement as well as a reduction in the environmental impact. This field of research has a deep impact in a large variety of industrial sectors (energy, machining tools, automotive, aeronautic, metallurgy, etc.). The challenge for most of these surface functionalization procedures is to get a strict control of the micro and nanostructure of the surface and interfaces that make possible the advent of new properties and applications that nanotechnology concept offers.
In this project, tailored nanostructured coatings for protection of components submitted to high temperature and aggressive environments are prepared seeking for an improved performance. This goal will be explored for three different applications that would contribute to an energy efficiency, renewable energies and solutions to decrease environmental impact. Based on the Cr-Al-N system, different coatings will be prepared by reactive magnetron sputtering technology changing chemical composition (metal content, incorporation of dopants like Y or Si); microstructure; phase distribution; architecture (multilayer/ nanocomposite) or more complex structures (tandem, multilayer gradient) on appropriated substrates depending on the foreseen application: a) oxidation resistance at high temperature (up to 1000ºC) for tool components; b) thermal stable solar selective absorber coating for mid (300-500ºC) and high temperature (>600ºC); c) corrosion resistant coating for supercritical turbine components (650ºC and 100% steam atmosphere).
The investigation of the oxidation mechanisms, phase transformations, structural modifications, etc. will be object of a careful study directly over the defined substrates for these applications to get fundamental knowledge on the degradation phenomena and protective effects. The establishment of the relationships between the initial properties and observed functional performance will enable the better understanding of the protection mechanisms and the optimization of such nanostructured coating systems for the selected application.
Keywords: Coating, high-temperature, oxidation-resistant, corrosion, nanostructured, energy, solar absorber, multilayer
Processing and microsctructural, mechanical and electrical characterization of ceramic-graphene composites
01-01-2016 / 31-12-2018
Research Head: Angela Gallardo López (UEI) / Rosalía Poyato Galán
Financial Source: Ministerio de Ciencia e Innovación
Code: MAT2015-67889-P
Research Team: Antonio Muñoz Bernabé, Felipe Gutiérrez Mora, Ana Morales Rodríguez
Nowadays, interesting prospects are proposed for ceramic-graphene composites, in application fields such as catalysis, energy storage and conversion, environment protection and biotechnology. A great effort is still required to answer open questions. Issues such as shear resistance of the ceramic-graphene interface essential to obtain an effective load transfer to the graphene sheets-, distribution of graphene in the ceramic matrix -to maximize the reinforcement mechanisms and electrical conductivity- and the high temperature mechanical
properties in these composites need special attention.
A systematic study of ceramic matrix graphene composites, including processing and microstructural, mechanical and electrical characterization is proposed in this project, with the aim of improving the comprehension of mechanisms controlling these properties when adding graphene nanostructures to a ceramic matrix.
Both alumina and yttria tetragonal zirconia (3YTZP) graphene composites will be processed by means of colloidal techniques. Special attention will be devoted to the dispersion of graphene in the ceramic matrix which is not a straightforward aspect, but is key to improve mechanical and functional properties. Sintering will be carried out by spark plasma sintering, SPS. Conditions will be optimized in order to obtain fully dense composites with nanometric grain size. Microstructural analysis will be performed by X ray diffraction, Raman spectroscopy, scanning and transmission electronmicroscopy (SEM and TEM). The present crystallographic phases, grain size and distribution of graphene nanostructures will be evaluated. In order to design advanced materials, it is necessary to study the relationship between microstructure and mechanical or electrical properties. Room temperature mechanical properties (hardness, fracture toughness and flexural resistance) will be characterized by indentation and bending tests at macro and microscopic scales. At high temperature, the plastic behavior of these ceramic-graphene composites will be assessed by creep tests under controlled atmosphere. Tribological behavior of the composites will also be studied to evaluate their resistance to wear. The electrical response will be assessed in a wide range of temperatures by means of complex impedance spectroscopy or by direct current conductivity measurements in the composites with lower resistivity. This is a most interesting property since it can be strongly increased when incorporating graphene to these ceramic systems.
Structured Catalytic Systems for Biofuel Production
01-01-2016 / 31-12-2018
Research Head: José Antonio Odriozola Gordón
Financial Source: inisterio de Economía y Competitividad
Code: ENE2015-66975-C3-2-R
Research Team: María Isabel Domínguez Leal, Anna Dimitrova Penkova, Francisca Romero Sarria
The dependence of our current energy system on fossil fuels and their harmful effects on the environment are strengthen the development of renewable energy sources. This is the case of the second generation biofuels. The production of fuels from lignocellulosic biomass and wastes very often involve catalytic processes that are characterized by strong heat exchange requirements due to the high thermal effect of the chemical reactions involved, as well as by the difficulty for simultaneously minimizing transport limitations and pressure drop in conventional fixed-bed reactors. Sometimes, extremely short contact times are also required. As a result, the conventional catalytic technologies operate under non-optimal conditions. The structured catalytic systems, structured catalysts and microchannel reactors offer excellent opportunities for overcoming those limitations because they efficiently allow to minimize simultaneously both the transport limitations and pressure drop while improving the radial fluxes of mass and heat and allowing very short contact times. The monoliths with parallel channels, open cell foams and stacked wire meshes can be made of a variety of metallic alloys and cells or pore densities. They can be also coated with any convenient catalyst thus becoming appropriate for the process of interest. On the other hand, the microchannel reactors are capable of providing an incomparable intensification of the process with an excellent temperature control, and improved product quality and process safety. The objective of this project is the investigation of the application of structured catalytic systems for the production of renewable fuels. The reactions investigated will be the Fischer-Tropsch synthesis, the direct dimethyl ether synthesis and the production of the syngas that will be fed to these processes through the reforming of biogas and producer gas. The water-gas shift reaction will be investigated as well due to its important role for adjusting the H2/CO ratio of the syngas. Special attention will be paid to the study of the effect of the thermal properties of the structured systems on their catalytic performance. To this end, the effects of the cells density of monoliths, pore density of foams, mesh of metallic wire meshes, type of metal alloy, thickness of the catalytic coating and substrate geometry (including in some cases microchannel reactors) will be investigated. Catalyst close to the state-of-the-art will be considered as the active phases. The development of these investigations will be supported by three transversal tasks led by each of the three participating research groups but in which all the groups will be involved: preparation of the structured catalytic systems, characterization using advanced techniques and modeling and simulation studies. This proposal aims at generating knowledge that helps to expand the current range of applications of the structured catalytic systems towards the field of sustainable energy applications that will benefit from the advantages of these systems in line with the challenge Safe, efficient and clean energy
Key words: Structured catalysts; Monoliths; Foams; Wire meshes; Microreactors; Second generation biofuels
Susteinable industrial waste treatment: designed adsorbent materials and bionanocomposites for inmobilizing heavy metals and fision products
01-01-2016 / 30-06-2019
Research Head: Maria Dolores Alba Carranza
Financial Source: Ministerio de Economía y Competitividad
Code: MAT2015-63929-R
Research Team: Miguel Angel Castro Arroyo, Ana Carmen Perdigón Aller, María del Mar Orta Cuevas
The focus of the project addresses the requirement of advanced environmental technology methodologies for removing pollutants. Recently, the interest and efforts to develop new technologies for more efficient treatments for the immobilization and the revaluation of hazardous waste are increasing in R & D plans. The overall object of the project is based on the design of a strategy of functionalization of highly charged swelling phyllosilicates and their later transformation on bionanocomposite for the effective retention and immobilization of hazardous waste, both cationic and anionic. This object represents a qualitative change in the work that is being nowdays developed in the field of model adsorbents systems with environmental applications that will improve the quality life of the population and the environmental conservation, because the designed functionalization of the synthetic silicates will allow the adsorption of a wide range of adsorbents in different oxidation states, cationic or anionic. The objectives are conformed to the Focus Area WASTE of the H2020 program and it is developed on the 2nd and 5th challenge of the H2020 program and on the 5th and 3rd challenge of the national research program.
The project has attracted interest from various observers companies, EPOs, (ENRESA and the Water and Local Energy Agency and Sustainability of the City of Seville), the public-private collaboration being promoted. Therefore, the research combines the basic principles of the National Strategy of Science and Technology: Putting the R&D&I at the service of citizens, social welfare and sustainable development, making the R&D&I a factor of improving business competitiveness (transfer of results to the private sector, see interest of EPOs) and recognize and promote R&D&I as an essential element for the generation of new excellence knowledge.
The viability of the proposal is ensured, first, because the research team, RT, has accomplished the synthesis of hydratable high charged phyllosilicates, with a novel and original method that allows setting the material desired charge, and, later, has successfully achieved their organofunctionalization (patent ES 2 362 597 B1). Second, the RT has developed the required methodology for the development of this project in closed scientific collaboration with other well recognized international groups (i.e. CNRS-University of Lille, University of Cambridge...). The RT enhances the clustering of their capabilities and scientific-technical skills which are essential to address this proposal with a remarkable transverse character.
Purely organic and hybrid organic-inorganic spin valves on supported nanowires produced by advanced vacuum and plasma-assisted deposition techniques
01-10-2015 / 30-09-2017
Research Head: Víctor López-Flores
Financial Source: Junta de Andalucia
Code: TAPOST-234
Research Team: Supervisor: Ana Borrás Martos. Componentes: Angel Barranco Quero, Francisco Aparicio, Juan Ramón Sánchez Valencia
The transition to organic electronics requires new devices on the nanometer scale composed only by organic materials, providing small, flexible, transparent and cheap devices. Among electronic devices, the spin valves have stood out for their rapid transfer from the experimental phase to the general public products, but a reliable organic spin valve nanometric device is yet to be developed.
The scientific objective of this project is to fill that gap. By using advanced, industrially scalable nanotechnology methods, we intend to produce a hybrid organic-inorganic and a fully organic spin valve in the form of a supported nanowire of ~200 nm width and several microns length, with a concentric spin valve stack. Three main fabrication techniques will be used: organic Physical Vapor Deposition (O-PVD), plasma-enhanced Chemical Vapour Deposition (PE-CVD) and remote plasma assisted vacuum deposition (RPAVD). Magnetoresistance measurements will be performed on single nanowires by conducting-probe atomic force microscopy (CP-AFM), and will give the definite measurement of quality of the samples produced.
This project will be developed within the Nanotechnology on Surfaces research group (NanoOnSurf), at the Institute of Materials Science of Seville (CSIC – University of Seville), located in the multidisciplinary CicCartuja research centre (Seville, Spain). State-of-the-art synthesis and characterisation techniques developed in the host research group will be the key for the success of this proposal..
This project is directly related with Horizon 2020 Work Programme 2014-2015, chapter 5.i, action ICT 3 – 2014: Advanced Thin, Organic and Large Area Electronics (TOLAE) technologies, and thus is expected to have a strong impact in the future European electronic industry.
PhoLED – Photonic Nanostructures for Light-Emitting Devices
1-09-2015 / 31-08-2017
Research Head: Hernán Míguez García
Financial Source: Unión Europea
Code: EU144490_01 Marie Curie Actions
Research Team: Dongling Geng
This project has received funding from the European Union’s H2020 Programme for research, technological development and demonstration under grant agreement no 657434.
The PhoLED project seeks to largely surpass the optical performance of state-of-the-art light emitters devised for illumination applications and contribute to solve some of the main technical limitations that the current technology presents. This project aims at integrating novel optical nanostructures and emitters, such as colloidal quantum dots or nanophosphors, to yield the next generation of light-emitting devices in which full spectral and angular control over the emission properties will be possible. The approach focuses on the development of: i) new synthetic routes to achieve efficient nanophosphors, and ii) preparation and processing strategies, based on surface textures and colloidal scatterers, to attain large area optical nanostructures possessing photonic properties that will allow a precise control on the intensity, angular distribution and color quality of light emission. Results achieved within this project will provide significant advance both in the comprehension of fundamental phenomena as well as in the development of versatile solid-state lighting devices of optimized efficiency, aiming to overcome technical barriers and maximize performance. The project’s outcome is twofold: a substantial expansion of the preparation of optical nanostructures to control light-mater interaction, and the practical realization of nanostructured lightemitting devices with unprecedented properties.
Application of advanced electron microscopy techniques to the characterization of nanostructured coatings for clean energy applications
01-03-2015 / 28-02-2017
Research Head: Ana María Beltrán Custodio
Financial Source: Junta de Andalucía
Code: TAHUB-050. Programa Talent HUB
This project is focus on the hydrogen generation and storage with the aim of producing hydrogen for clean and sustainable energies. It happens due to an exothermic reaction where a catalyst is required to do so safety. Catalysts based on noble metals are good candidates for this purpose such as, cobalt, cupper… Here, the complete catalysts systems and different supports are studied. They have been grown by magnetron sputtering technology. The structure and composition are studied, up to nano-scale, by advanced scanning-transmission electron microscopy techniques, (S)TEM, such as high-resolution (HRTEM), high-angle annular dark field (HAADF), energy dispersive X‑Ray (EDX), electron energy loss spectroscopy (EELS), for chemical analysis. Furthermore, the use of the three-dimensional characterization technique electron-tomography provides a full understanding of the analysed material. The combination of structural and compositional analytical microscope techniques, in both STEM and TEM mode, allows a full nano-characterization of the systems. The (S)TEM analyses are the essential tool to determine the relationship among the microstructure, the growth conditions and the final behaviour and properties of the systems which will help to improve them and, therefore, to contribute to the production of clean energy.
This project has four main strategic objectives:
1. Nano-materials for sustainable energy applications. Materials for the production, use and storage of Hydrogen.
2. Development of sputtering technology for the fabrication of nanostructures (thin films, coatings and controlled microstructure multilayers).
3. Development of the potential capabilities of the Laboratory for Nanoscopies and Spectroscopies (LANE).
4. Use of advanced structural and analytical techniques for the nano-analysis of new nanomaterials.
Adsorption mechanisms study of harmful anionic pollutants by tailor-made aluminosilicates
01-02-2015 / 28-02-2017
Research Head: Esperanza Pavón González
Financial Source: Junta de Andalucía
Code: TAHUB-082. Programa Talent HUB
The scientific, technological and industrial development carried out in the second half of last century has caused an increasing pollution in the natural environment. Consequently, a widespread recognition of the need to develop technologies and strategies for pollution control has arisen in the recent times. The main objective of this Project is to design swelling layered silicates of high charge and their surface modification for an effective activity with respect to the retention and immobilization of toxic and dangerous anionic wastes.
The proposed methodology consists on the synthesis of high charge swelling mica with isomorphic substitution of Si4+ by Al3+ with a charge density in the range of brittle mica but with a cation exchange and swelling capacities unusual in these silicates. In order to enhance the anionic adsorption capacity, the mica will be functionalized in the surface with magnetite and with the inclusion of alkylammonium cations in their interlayer space.
An immobilization protocol of harmful anionic products like AsO42-, SO42- will be established, using the best adsorbent in function of both the structure and the funcionalization of the highly charged swelling mica. Afterwards, the applicability of these adsorption reactions will be tested in actual contaminated soils from Chili and Spain.
Development of cermets with high entropy alloys as binder phase for machining applications
01-01-2015 / 31-12-2018
Research Head: Francisco José Gotor Martínez
Financial Source: Ministerio de Economía y Competitividad
Code: MAT2014-52407-R
Research Team: José Manuel Córdoba Gallego, María Dolores Alcalá González, Pedro José Sánchez Soto, Concepción Real Pérez, María Jesús Sayagués de Vega
Machining is an essential part of the manufacturing processes in many industries and has significant economic implications, as it represents an important proportion of the total manufacturing cost. The success of machining depends on many factors, among which the correct choice of the cutting tool. High-speed machining and difficult-to-cut materials, such as superalloys employed in the fabrication of aircraft engines, impose extreme working conditions to cutting-tools, which are characterized by high temperatures, pressures and tensions that can lead to the premature failure in service. Furthermore, the deterioration of the cutting-tool due to an excessive wear and deformation makes it difficult to maintain the tolerances and the surface integrity of the workpiece, severely compromising the fatigue properties and, therefore, its applicability and lifetime. The European industry has as a main objective to improve the productivity, accuracy and quality of these highly-demanding machining processes, stimulating the search for new cutting-tool materials that are better suited to these new requirements.
Cermets have properties, such as high wear resistance, high chemical stability and good mechanical strength at high temperature, well-adapted to the requirements of these machining processes. But for a realistic application, it is necessary to significantly increase the fracture toughness and damage tolerance to values close to those of cemented carbides. In the last few years, there has been an ongoing process of cermets optimization, mainly by modifying the microstructure and chemical composition of the ceramic phase. In a previous project (MAT2011-22981), we have shown that the so-called complete solid solution cermets, characterized by single phase ceramic particles consisting of a complex carbonitride, allow achieving a good combination of hardness and fracture toughness.
In this new project, which can be considered as complementary to MAT2011-22981, we propose to further improve the properties of cermets, also acting on the binder phase as it is ultimately responsible for the cohesion and toughness of the material. High entropy alloys (HEAs), which are composed of at least five major metal elements in equal or near equal atomic percent (as opposed to traditional alloy systems that are typically based on only one or two major elements), can be postulated as suitable to replace current binder phase in cermets. These alloys often exhibit superior properties than conventional alloys, including high strength and ductility at high temperature and good wear and corrosion resistances. The main goal of this project focuses on the development of complete solid solution cermets with HEAs as the binder phase. The cermets to be developed will have a simple microstructure; similar to cemented carbides, but high compositional complexity, since the two constituent phases (ceramic and binder) will be complex solid solutions with a high number of components (at least five). With these new cermets, we try to maintain their current optimal properties, while improving those limiting their potential use in the most demanding machining processes.
Advanced optical materials for efficient optoelectronic devices
1-01-2015 / 31-12-2017
Research Head: Hernán Míguez García / Manuel Ocaña Jurado
Financial Source: Ministerio de Economía y Competitividad
Code: MAT2014-54852-R
Research Team: Ana Isabel Becerro Nieto, Nuria Núñez Alvarez, Mauricio E. Calvo Roggiani, Gabriel Lozano Barbero, Juan Francisco Galisteo López, Miguel Anaya Martin
The MODO project will focus on the development of optical materials to optimize the performance of optoelectronic devices such as solar cells or light emitting devices, thereby improving their energy conversion efficiency. The main objective of this proposal is to increase their performance by controlling light absorption and emission processes occurring in the materials composing these devices. This will be achieved through the design and integration of photonic nanostructures whose properties are also compatible with the manufacture and operation requirements of these systems, such as thermal, chemical and mechanical stability, durability, ease of processing and scale-up.
Development of catalytic and photocatalytic processes for natural gas valorization: Activation and transformation of methane and light hydrocarbons
1-01-2015 / 31-12-2018
Research Head: Alfonso Caballero Martínez
Financial Source: Ministerio de Economía y Competitividad
Code: CTQ2014-60524-R
Research Team: Juan Pedro Holgado Vázquez, Gerardo Colon Ibáñez, Rosa María Pereñiguez Rodríguez, Alberto Rodríguez Gómez
The present project intends to study and develop different methane activation and transformation processes to obtain high value added molecules.
For this scope we propose to study well established processes of indirect conversion, through reforming reactions (RM) for syngas production, as well as those direct conversion ones, particularly the direct oxidation to methanol (DOM) and aromatization of methane (DAM).
Regarding to the methane reforming reaction, we propose the development of catalytic systems with improved resistance against deactivation processes. In this case, we would prepare and characterize new nanostructured bimetallic catalysts based on nickel supported on ceria, alumina, or alumina/ceria, as well as mesoporous SBA-15 supports, doped with ceria and alumina. As a second metal we would use cobalt or iron. At the same time, we would perform the study of the reforming reaction by a photocatalytic process using Cu, Pt and Ni doped photoactive systems such as titania or ceria, and others recently proposed as Ga2O3, carbon nitride or graphene. In this case, we propose to explore the possibility of the photochemical activation for the preferential oxidation of CO (photo-PROX) in the presence of hydrogen, a very usefulness process for hydrogen purification from syngas synthesis. We will focus our attention in the preparation of systems with the appropriate band structure for the control of the selective oxidation of CO.
Concerning to direct conversion processes, we would study the direct oxidation of methane (DOM) using O2, H2O2, or N2O as reaction activators, in combination with systems based on Au/Pd, Fe, Cu and/or Ni deposited on different supports as ZSM-5, graphene and TiO2. In this later case, using Au/Pd as the active metallic phase in the presence of H2O2, we propose the possibility to combine the synthesis of H2O2 in situ with the subsequent direct oxidation of methane.
Moreover, we would explore the photocatalytic oxidation of methane to methanol as a novel and highly attractive alternative. In this case, the use of new photocatalytic materials as BiVO4 and the presence of redox mediators would allow us to control the selective photo-oxidation to methanol.
Other catalytic systems closely related to above mentioned, and in particular those based on Mo supported on ZSM-5 and MCM-22 zeolites, would be used for the methane aromatization reaction study. The aluminiun ratio, Mo loading and its activation in the microporous structure of the suport, as well as the addition of certain promoters as Ga, Tl or Pb would be some of the parameters to be optimized for this reaction. At the same time, recently reported photoinduced aromatization process would be studied.
Hybrid thermochemical storage of concentrated solar energy SOLARTEQH
01-01-2015 / 31-12-2017
Research Head: Luis Allan Pérez Maqueda
Financial Source: Ministerio de Economía y Competitividad
Code: CTQ2014-52763-C2-1-R
Research Team: María Jesús Diánez Millán, José Manuel Criado Luque
There are current projects within the Sunshot (USA) initiative and UE FP7 program in which the feasibility of fluidized beds for permanent chemical storage of concentrated solar energy is analyzed. One of the materials considered is the cheap and abundantly available natural limestone (CaCO3). Using a CO2/air mixture in suitable relative proportions according to the operating temperatures (600-900ºC), CaCO3 would be decarbonated by endothermic reaction in periods of high irradiation or the CaO would be carbonated releasing heat when the temperature falls below a certain value. By varying the %CO2 in the fluidization gas, either decarbonation or carbonation would be provoked as desired to reduce or increase the bed temperature based on the intensity of solar radiation and electricity demand. This control would help to alleviate the effect of the variability of sunlight intensity. Besides of the permanent storage of energy, the energy density of CaCO3 (about 1 MWhr/m3) is greater than that of molten salts currently used in commercial plants (0.25-0.40 MWhr /m3). Furthermore, natural limestone is non-corrosive material, not degradable and would allow operation at higher temperatures thus increasing the thermoelectric conversion efficiency. However, the fluidization of limestone is typically very heterogeneous, being characterized by the formation of gas channels and large unfluidizable aggregates in the bed which greatly reduce the effectiveness of solid/gas contact and thus the heat transfer efficiency of the reaction. On the other hand, other projects have leaded to the development of successful small-scale pilot plants based on the thermal storage in fluidized beds of inert solids with high heat capacity such as fine silica sand or silicon carbide with good fluidization properties and thus characterized by a high heat transfer. However, these systems present unavoidable heat losses and large volumes are needed to ensure a supply of heat to the power cycle in periods of low solar irradiation. Our project is based on synergistically combine the heat storage in fluidized beds of fluidizable inert solids (such as sand) with the permanent chemical storage of CaO precursors (such as natural limestone) by the use of fluidized beds of mixtures of both granular materials. Experimental measurements will allow characterizing the behavior of the sand/natural limestone mixtures for the transfer and storage of concentrated solar energy. The working plan shall limit the optimum concentration of CO2 in the fluidizing gas and proportion of sand/limestone as a function of temperature for optimizing the energy storage efficiency. The physic-chemical properties of mixtures of sand/limestone that favor heat transfer and storage according to the intensity of solar radiation will be delimited. Also thermal and chemical stabilization methods will be explored in order to increase the reversibility of the carbonation/calcination reaction under practical conditions. In parallel, a thermodynamic modeling work will be carried out that includes processes that affect the energy efficiency and serve as a starting point to establish optimum operating parameters with the ultimate goal of transferring the knowledge to the technology sector. For this final purpose the project has the support of Abengoa Solar.
Ferroelectric polymer-based piezoelectric nanogenerators for energy harvesting and sensor applications
01-10-2014 / 30-09-2016
Research Head: Pedro E. Sánchez Jiménez
Financial Source: Junta de Andalucia
Code: TAPOST-134. Programa Talent HUB
Harvesting energy from ambient sources in our environment has generated tremendous interest as it offers a fundamental energy solution for small-power applications including, but not limited to, ubiquitous wireless sensor nodes, portable, flexible and wearable electronics, biomedical implants and structural/environmental monitoring devices. As an example, consider that the number of smart devices linking everyday objects via the internet is estimated to grow to 50 billion by the year 2020. Most of these “Internet of Things” devices will be extraordinarily small and in many cases embedded, and will wirelessly provide useful data that will make our lives easier, better and more energy-efficient. The only sustainable way to power them is using ambient energy harvesting that lasts through the lifetime of the product, and hence the need for commercially viable small‑scale energy harvesters that can operate in any environment. In this context, energy harvesting from ambient vibrations is particularly attractive, as these are ubiquitously available and easily accessible, originating from ever-present sources such as the moving parts of devices and machines, fluid flow and even body movements. Nanoscale piezoelectric energy harvesters, also known as nanogenerators2, are capable of converting small-scale vibrations into electrical energy, thus offering a means of superseding batteries that require constant replacing/recharging, and that do not scale easily with size. Nanogenerators can thus pave the way for the realization of the next generation of self-powered electronic devices, with profound implications in disciplines as far-reaching as biomedicine, robotics, smart environmental monitoring and resource management, to name a few. Nano-piezoelectric energy harvesting is an emerging technology and this proposal is designed to tackle the challenge of developing novel materials with enhanced piezoelectric properties that are cheap, environment-friendly, bio-compatible and easily integrated as nanogenerators into electronic devices.
Synthesis and properties of luminescent nanoparticles for biomedical applications
01-10-2014 / 30-09-2016
Research Head: Alberto Escudero Belmonte
Financial Source: Junta de Andalucia
Code: TAPOST-234
Luminescent nanoparticles are currently attracting wide research interest in Nanobiomedicine due to their applications, ranging from optical biolabels for imaging of tissues or intracellular structures to sensors to detect biological molecules, and as tracking devices. This project is focused on the design of new, cheaper, and environmentally friendly synthesis methods of uniform luminescent nanoparticles, such as rare earth doped fluorides, phosphates, molybdates, and vanadates. It also evaluates their biomedical applications, with especial attention to their sensing properties and their ability to detect tumour cells. This scientific work includes the characterization of the resulting materials, the optimization of their optical and magnetic properties, and the development of different functionalization processes. The final step of this research project deals with the study of the interaction of the functionalised nanoparticles with cells of different nature, and includes cytotoxicity studies, with special attention to the role played by the morphology and chemistry of the particles.
Integration of Photonic Nanostructures in Flexible Dye Solar Cells
1-07-2014 / 30-06-2016
Research Head: Hernán Míguez García
Financial Source: Unión Europea
Code: FP7-PEOPLE-2013-IIF Marie Curie Actions
Research Team: Yuelong Li
It is the main goal of this project to bring to the host institution and the European Research Area the knowledge and technology to prepare current record flexible dye sensitized photovoltaic devices, previously developed by the candidate in South Korea and then the USA, in order to be able to further improve them, while endowing them with semi-transparency, using stretchable and bendable optical materials. The candidate has demonstrated that several key materials and processes provide better
performance of bendable dye solar cells, i.e., enhanced efficiency and flexibility, by allowing the preparation of electrodes in which the electron diffusion length is longer and charge collection efficiency is consequently enhanced. However, highly efficient dye solar cells are opaque as a consequence of the particular diffuse scattering design employed to improve light absorption, which limits their application in building or automotive integrated photovoltaics. This proposal seeks to solve such drawback by
introducing photonic nanostructures in different configurations, yielding both light harvesting enhancement and preserving transparency, hence placing Europe at the forefront of research in this specific area within the field of renewable energy. This final goal will be attempted through different approaches, each one challenging from the materials science perspective. Preparation of such highly efficient and transparent devices will combine the flexible solar cell processing tools previously developed by the candidate with the versatile optical material preparation techniques pioneered by the host institution. More specifically, integration of novel porous flexible photonic structures into the light harvesting layer, use of flexible mirrors attached to the back of the counter-electrode, and designed distribution of scatterers will be employed to
reach the target.
Development of processes for the catalytic combustion of hydrogen and study of the integration in devices for portable applications
16-05-2014 / 15-05-2016
Research Head: Asunción Fernández Camacho
Financial Source: Junta de Andalucía
Code: P12-TEp-862
Research Team: Julián Martínez, Gisela Arzac, Dirk Hufschmidt, Joaquín Ramírez, M.Carmen Vera, Vanda Godinho, Lionel Cervera, T.Cristina Rojas, Olga Montes, Mariana Paladini, Jaime Caballero-Hernández
Hydrogen is an attractive candidate as a vector for storage and transport of energy in the context of an increased use of renewable and clean energies. The production and use of energy based on hydrogen technology is particularly important for small-scale portable (and potentially scalable for stationary) applications. In this project the process of catalytic (controlled) combustion of hydrogen will be investigated in the various aspects that could lead to a final integrated configuration with a H2 generation system for portable applications. For that the project will take advantage of the synergy of integrating two researcher groups from the PAI: i) The TEP217 group, specialists in storage and generation of hydrogen based on metal hydrides, complex hydrides and hydride composites reactive systems; and in the use of catalysts and additives to control and improve the kinetics of these processes. ii) The FQM342, specialist group for the fabrication of porous ceramics of high interest as catalyst supports for harsh combustion environments. Further collaboration is completed with the participation of the company Abengoa Hidrógeno SA that will be involved as sub-contractor as specialist in systems for the production and storage of hydrogen.
In particular we will work on this project in the following lines:
1.- Development of catalysts and supports for catalytic combustion. Typically porous biomorphic silicon carbide ceramics and classic noble metal catalysts, as well as new low cost catalysts to be developed in the project.
2.- Development of reactors needed for the study of the catalytic combustion. Typically hydrogen flows from a few ml/min to the scale of a H2 generator already available in the range 0.5 to 1.5 L/min.
3.- Coupling the catalytic combustion system with a portable hydrogen generation systems that we have developed in previous projects.
4.- Application of the sputtering technology in an exploratory manner in this project to deposit the catalyst materials for the H2 catalytic combustion on porous substrates.
5.- Microstructural and chemical characterization of the supports and catalysts in the nanoscale to follow the procedures of synthesis and evolution in operation.
Inmobilization of heavy metals by synthetic high-charged organomicas: Test at laboratory scale
16-05-2014 / 16-02-2019
Research Head: María Dolores Alba Carranza
Financial Source: Junta de Andalucía
Code: P12-FQM-567
The focus of the project addresses the environmental technological requirement to develop advanced methods for removing pollutants. The interest and efforts to develop new technologies aimed at more efficient treatment in detention and revaluation of hazardous waste is increasing in R & D plans. It is in this scenario where this project should be framed and in particular in the framework of the management of heavy metal cations, issue of high public interest in this decade.
Since the second half of the twentieth century, humanity has faced a huge scientific and technological development that is responsible for increased environmental pollution. As an example, we can mention two problems that are currently of concern and action of the Andalusian: Andalusian coastal pollution and urban wastewater. Therefore, this is a complex problem that pollutants sources are varied of origin and routes followed by various pollutants are diverse and, frequently, it is beyond the control necessary to avoid urban undesirable effects on the natural environment and. Therefore, a basic level research is demaned to implement the necessary mechanisms for the immobilization of such harmful cations.
The objectives and scope of this project are based on advances made by other research groups in the management of these types of contaminants and the latest research conducted by the research team that allowed design expandable high-charged layered silicates with special properties as precursors for the retention of harmful residues. Therefore, it is proposed in this project the organofunzionalization of such synthetic micas with thiol groups or alkylammonium cations of varying chain length and evaluation of its adsorption capacity and irreversible retention of heavy metals.
Synthesis and characterization of non oxide ceramic obtained by the thermal decomposition of polymeric precursors
16-05-2014 / 15-05-2016
Research Head: Pedro E. Sánchez Jiménez
Financial Source: Junta de Andalucia
Code: TEP-1900
Research Team: Antonio Perejón Pazo, Cristina García Garrido
There has been a substantial interest during the last years in polymer derived ceramics due to the wide array of interesting properties they exhibit. This type of ceramic, best known by the acronym PDCs, are obtained by the thermal decomposition of a polymeric precursor and are mainly non oxidic, such as SiC, Si3N4, BN, etc. PDCs exhibit a wide array of thermomechanical and electrical properties of great interest, as well as a high thermal and oxidation resistance which make them promising candidates for working under extreme environmental conditions. Thus, several potential applications ranging from nanotechnology to aeronautics have been proposed. A big advantage of these materials is that their properties depend on both the chemical properties of the original polymeric precursor and the processing conditions. Therefore, by carefully selecting the precursor and the experimental degradation conditions it would be possible to tailor the properties of the final ceramic. Moreover, the temperatures needed to prepare these ceramics are much milder than those required by means of conventional ceramic processing or powder consolidation techniques. However, there is an important disadvantage that has severely limited their usability in that cracks are formed during the transformation into a ceramic so that the final pieces might be rendered unusable. Despite the important of processing, there are few systematic studies assessing the influence of ceramification conditions on the final properties. In this proposal, we plan to use smart temperature controlled methods to study the synthesis of different types of PDC. This methodology allows for great precision in the control of experimental conditions such as temperature and gas pressure and has been previously proved useful to help control the microstructure of materials synthesized by thermal transformations from precursors. Thus, we plan to use this methodology to synthesise defect-free PDCs and to study the influence of experimental conditions on the nanostructure and properties of the final ceramic material. At the same time, the information provided by the systematic study will help to better comprehend the underlying physics of the as yet poorly understood polymer-ceramic transformation. The prepared powders will be characterised in terms of nanostructure and properties such of piezoresistivity, porosity, lithium insertion capability and oxidation resistance.
Highly optimized unit for a sustainable enhanced solar system HOUSESS
03-02-2014 / 31-12-2017
Research Head: Hernán Míguez García
Financial Source: Ministerio de Economía y Competitividad
Code: RTC-2014-2333-3 (Programa Retos)
Research Team: Juan Francisco Galisteo López, José María Miranda Muñoz
The aim of the project is the design, development, prototyping and validation of a hybrid photovoltaic-thermosolar system that allows the storage and manageability of the generated solar energy. This integrated system will generate electricity at lower costs than standard thermosolar technology.
The hybrid system consists of a parabolic cylinder system and a low concentration photovoltaic solar receiver. Between these two components a dichroic filter is placed, which receives the reflected light from the parabolic cylinder primary mirror and allows the selective separation of the solar spectrum, letting pass a portion of the light to the photovoltaic receiver and reflecting the rest to the thermal tube receiver. Said dichroic filter sends to the photovoltaic receiver photons with wavelengths which are more efficiently absorbed by the solar cell. The thermal part of the system also shows the ability to controllably deliver power, allowing energy storage for its use in the most suitable moment of the day.
Dielectric Barrier Discharge plasma for the developing of industrial process at atmospheric pressure (DBD-Tech)
30-01-2014 / 29-01-2017
Research Head: José Cotrino Bautista
Financial Source: Junta de Andalucía
Code: P12-FQM-2265 (Proyecto de Excelencia)
Research Team: Francisco José García García, Jorge Gil Rostra, Richard M. Lambert, Manuel Macías Montero, Alberto Palmero Acebedo, Victor Rico Gavira
This research project aims first the study of different unknown basic aspects of the construction of the dielectric barrier discharge, better design conditions for: barrier electrodes, the design of the metallic electrodes and dielectrics and to know the best working conditions (size and operation frequency) for the plasma. One goal is to control the lateral functionalization of advanced materials and other objective, is the discovering of new plasma catalysis processes that can increase selectivity and the reduction of energy consumption by plasma chemical reactions in controlled industrial processes of high added value and/or impact. It is expected for both applications, a clear advance in optimization of the industrial process.
Bio-ceramics for diesel engine particulate filters
01-01-2014 / 31-12-2016
Research Head: Julián Martínez Fernández / Ricado Chacartegui
Financial Source: Ministerio de Economía y Competitividad
Code: MAT2013-41233-R (Programa Retos)
Research Team: José Antonio Becerra Villanueva, Alfonso Bravo León, Manuel Jiménez Melendo, Antonio Ramírez de Arellano López, Joaquín Ramirez Rico, Francisco Varela Feria
The importance of controlling particulate emissions from diesel engines is essential given its volume and the associated environmental and economic impact. Control systems based on modifications of the combustion process in the engine are not sufficient to meet the requirements of current regulations, less future ones, and therefore it must necessarily be employed post treatment systems such as filters. There is considerable scope for improving them both in reliability, degradation of control performance, durability, multifuel operation and cost reduction.
This project will assess the development and manufacturing of regenerative particulate filter for diesel engines to improve the current system specifications, based on a new generation of ceramic bio-derivated materials, with integrated systems for particle combustion. This objectives will be achieved integrating researchers synergies from: i ) Thermal Engines and Machines Group, GMTS , specialists in internal combustion engines ii ) Multifunctional Biomimetic Materials Group, MBM, specialists in obtaining bio-derivated porous ceramic as well as physical, chemical and microstructural characterization. In addition, the project is completed with the collaboration of companies in assessing technology and its industrial applicability.
The following research lines will be addressed:
- Determination of processing routes that enable the development of filter elements with suitable physical, and chemical properties, based on prior knowledge in bio-derivated materials and new technologies regarding the use of SiO2 gels.
- Identification of suitable catalysts and systems for its deposition.
- Manufacture of the filter elements consisting of porous support and catalyst.
- Thorough characterization of the physical, chemical and microstructural properties of interest for the application.
- Development of activation systems for the filter regeneration.
- Design and manufacturing of the filters with suitable geometry and prototype dimensions.
- Pilot unit design and study of the integration and operation of engine.
- Final design of the filter for industrial facility.Previous studies developed by MBM in these bio-derivated materials have demonstrated their potential as gas filter elements at high temperatures in coal gasification plants, which supports the likelihood of success of this project, which will address the improvements needed to develop the technology in the combustion conditions of diesel engines, under dynamic conditions in vehicles and regenerative filters.
A reduction of pollutant emissions from diesel engines would have a great environmental impact, health and economic development, with about 100 million diesel vehicles circulating in Europe and a related industry with over 2 million direct jobs and growing trend in market. This project addresses the Social Challenge 3 Horizon 2020, Secure, clean and efficient energy. In addition, using bioceramics allows replacement of metal components used today, which also aligns with the Social Challenge 5 of the Horizon 2020 in search of alternatives to essential raw materials in existing applications by reducing dependence on imports and sustainability of applications.
Development of Biomorphic Catalysts from Residual Biomass for Hydrogen Production and Bio-oil Refining
1-01-2014 / 31-12-2018
Research Head: Miguel Angel Centeno Gallego
Financial Source: Ministerio de Economía y Competitividad
Code: ENE2013-47880-C3-2-R
Research Team: María Isabel Dominguez Leal, Carlos López Cartes, Leidy Marcela Martínez Tejada, Svetlana Ivanova
The main goal of this coordinated project among the Universities of Zaragoza and the Institute of Material Science of Seville is the development of supported metal catalysts on biomorphic carbons (CB) for their subsequent application in the hydrogen production and in the refining of bio-oil processes. Biomimetic mineralization is a powerful tool that takes structures formed by a biological process as templates to synthesize inorganic functional materials. It offers the advantage to fabricate materials that are difficult to produce by top-down fabrication methods and that have chemical compositions which cannot be produced by self-assembly. Given that the wood is a multifunctional material that is structured on several levels of hierarchy, a large variety of ceramic microstructured materials can be prepared using lignocellulosic materials (biomass). However, the replication of the different hierarchical levels present in vegetal tissues still remains as great challenge today. In order to get a deeper acknowledgement in this subject, this proposal is going to study the synthesis, characterization and application of metallic catalysts supported on biomophic carbons (Me/CB), prepared with uniform size distributions, and hierarchical porosity.
The preparation of the biomorphic materials will be carried out by thermal decomposition in a reducing (or inert) atmosphere, at high temperature, and high heating rates, of several lignocellulosic components (eg cellulose, lignin, paper) impregnated with catalytic metallic precursors. In this way, in a single step, it is possible to obtain a biomorphic carbonaceous support with the metallic nanoparticles dispersed on its surface. This method of synthesis of catalysts has an outstanding versatility because allows the use of different lignocellulose raw materials, with a large variety of compositions and metal contents. In addition they can be easily structured in monolithic devices or foams. As raw materials, besides cellulose, lignin or paper, it is going to be studied several types of waste agricultural biomass.
The obtained Me/CB catalysts will be applied in hydrogen production processes (light hydrocarbons and ammonia decomposition, dehydrogenation of formic acid), water-gas-shift reaction, and in several reactions test of refining of bio-oil (conversion of acetic in acetone, hydrogenation of vanillin and cyclohexene, and conversion of m-cresol into phenol).
Environmental and process monitoring with responsive devices integrating nanostructured thin films grown by innovative vacuum and plasma technologies
01-01-2014 / 31-12-2017
Research Head: Agustín R. González-Elipe
Financial Source: Ministerio de Economía y Competitividad
Code: MAT2013-40852-R
Research Team: José Cotrino Bautista, Ricardo Molina Mansilla, Victor Rico Gavira, Francisco Yubero Valencia, Juan Pedro Espinós Manzorro, Alberto Palmero Acebedo, Angel Barranco Quero, Fernando Lahoz Zamarro
This project aims at the development of a new generation of low dimensional responsive systems and sensors that integrate nanostructured layers with well-controlled electrical and optical properties which, prepared by innovative vacuum and plasma methods, present a tunable and high porosity and are able to actively interact with the environment. The basic principles of the oblique angle approach (OAD) during the physical vapor deposition (PVD) of evaporated thin films will be extended to the fabrication of similar layers by plasma and magnetron sputtering techniques. Combination of these techniques along with other innovative plasma technologies, including atmospheric pressure plasma deposition or plasma-evaporation polymerization will be employed to achieve a strict control over the nanostructure and properties of final films and complex systems . Supported metal and oxide nanostructured thin films, stacked multilayers and hybrid and composite suported nanostructures will be prepared and thereafter characterized by advanced electron and proximity microscopies and other techniques. Process-control strategies will be implemented in order to understand the fundamental mechanisms governing the film structurations and to propose new synthetic routes scalable to industrial production so as to achieve tailored morphologies and properties for these porous thin film materials. Highly ordered and homogenous arrays of these nanostructures will be used as ambient temperature gas and liquid sensors, microfluidic responsive devices and intelligent labelling tags. For these applications the supported porous thin films will be suitably functionalized with metal nanoparticles, grafted molecular chains or layers of other polymeric materials. They will be also stacked in the form of vertically ordered photonic structures. Innovative device integration approaches including the water removal of evaporated sacrificial layers of NaCl and their integration in the form of microdevices will be carried out to fabricate advanced sensors, microreactors and responsive systems. Photonic, electrical and/or electrochemical principles of transduction will be implemented into the devices for detecting and/or fabricating i) oxygen and chlorine in solutions, ii) glucose and organic matter in water iii) gas and vapor sensors or iv) inteligent labels. Specific applications are foressen for the control of the outside environment (air and waters), industrial and greenhouse locations, agroindustrial processes such as fermentation and the tracking and trazability of different kinds of goods and foods.
It is expected that the combination of scientific breakthroughs in thin film technology and new film engineering principles at the micro- and nano-scales will open new areas of research with a high impact in key enabling technologies such as photonics, nanotechnology, advanced materials and in other fields like plasma technology and microfluidics.
New multifunctional 1D hybrid nanostructures for selfpowered nanosystems
1-01-2014 / 31-12-2016
Research Head: Ana Isabel Borrás Martos
Financial Source: Ministerio de Economía y Competitividad
Code: MAT2013-42900-P
Research Team: José Cotrino Bautista, Ricardo Molina Mansilla, Juan Pedro Espinós Manzorro, Ana Isabel Borrás Martos, Angel Barranco Quero
HYBR(1)D is a multidisciplinary Project that aims the development of novel multifunctional nanostructured materials for applications as renewable energy devices, photonics and device miniaturization. The main objective of the project is the development of original synthetic strategies for nanostructured 1D materials like organic and inorganic nanowires and other hybrid hetero-structured systems. Special attention will be paid to the development of coaxial “core@shell/multi-shell” structures integrating organic, metallic and oxide nanostructured components. These materials will be synthesized using an innovative methodology compatible with processable substrates of different nature that will be fully scalable to industrial production. In addition, the project also included exploratory studies about self-supported composite membranes where the nanostructured 1D materials will be embedded.
A second project objective is to probe the functionality of the novel 1D nanostructures in different applications under the global strategy that we defined as development of “selfpowered nanosystems”. These applications are: energy power generation devices (solar cells and piezoelectric nanogenerators) and nanosensors. It is worthy to notice that although the materials under study are relatively diverse, from semiconducting inorganic nanotubes (TiO2, ZnO) to organic single-crystal nanowires (“small molecules”) or hybrid heterostructures, the synthetic vacuum methodologies are, in all the cases, very similar and easily adaptable. These methodologies are physical vapor deposition (organic molecules), plasma assisted vacuum deposition (organic molecules and inorganic oxides), metal dc-sputtering and oxygen plasma etching. All of them can be used sequentially or in combination and are integrated in the same reactors. The project PI and the Nanotechnology on Surface group from the ICMS-CSIC have a solid background in the use of plasma and vacuum technology for the study of functional thin films and devices that is being extended to the field of 1D supported nanostructures in the recent years. HYBR(1)D project intend to cover all the scientific-technological chain from the materials development to the final applications including advanced characterization, flexible synthetic routes, device integration and testing at laboratory scale.
Microfluidic integrated sensors for the control of fermentation
2-12-2013 / 31-12-2015
Research Head: Agustín R. González-Elipe
Financial Source: Ministerio de Economía y Competitividad
Code: RECUPERA2020 - 1.4.1
Research Team: Juan Pedro Espinós Manzorro, José Cotrino Bautista, Francisco Yubero Valencia, Alberto Palmero Acebedo, Angel Barranco Quero, Ana I. Borrás Martos, Victor J. Rico Gavira, Rafael Alvarez Molina, Pedro Angel Salazar Carballo
The objective of this Project is the development of new integrated and robust micro/nano- fluidic systems that enable the reliable incorporation of control tests, sensorization and rapid analysis of agrofood products, mainly liquids or soluble. The technology to be developed should be applied to final products, as well as during their different elaboration steps. IN particular, a niche of application that will be directly addressed in the project is the control of fermentation process with the development of new integrated fluidic transductors that permit the quantitative detection of glucose and/or other sugars by means of electrochemical and photonic developments integrated in microfluidic and similar devices.
New materials for advanced packaging, intelligent label-ing, anti-counterfeiting and monitoring of agricultural and livestock products
02-12-2013 / 31-12-2015
Research Head: Angel Barranco Quero
Financial Source: Ministerio de Economía y Competitividad
Code: RECUPERA2020 - 1.4.2
Research Team: Ana Isabel Borrás, Francisco Yubero, José Cotrino, Juan Pedro Espinós, Juan Ramón Sánchez Valencia, Francisco Javier Aparicio Rebollo
This Project intends the development of novel materials and processes for intelligent labeling of agricultural and livestock products to improve their traceability. The project is based on the development of active optical structures, laser processing strategies and the fabrication of practical testing prototypes.
Purification of air in greenhouses and food processing centers
2-12-2013 / 31-12-2015
Research Head: José Cotrino Bautista
Financial Source: Ministerio de Economía y Competitividad
Code: RECUPERA2020 - 2.2.3
Research Team: Ana María Gómez Ramírez, Antonio Méndez Montoro de Damas
This project is related with a technology to generate a cold plasma at atmospheric pressure with air flowing through a reactor. The specific objective of this activity is the development of a prototype air purification system for greenhouses, food processing centers, livestock enclosures, or other similar types of markets or enclosures where the concentration of gases harmful to the health of the workers can be very significant by the use of insecticides, fungicides, disinfectants or other compounds. The developed system should be able to purify the air in closed installations and where a large number of chemicals, mainly volatile organic compounds, accumulate in the air that is handled. The cold plasma reactor technology design follows the characteristics of packed-bed dielectric barrier discharge by using ferroelectric dielectric.
New materials for advanced packaging, intelligent labeling, anti-counterfeiting and monitoring of agricultural and livestock products
01-12-2013 / 31-12-2015
Research Head: Angel Barranco Quero
Financial Source: Ministerio de Economía y Competitividad
Code: RECUPERA2020 - 1.4.2
Research Team: Ana Isabel Borrás, Francisco Yubero, José Cotrino, Juan Pedro Espinós, Juan Ramón Sánchez Valencia, Francisco Javier Aparicio Rebollo
This Project intends the development of novel materials and processes for intelligent labeling of agricultural and livestock products to improve their traceability. The project is based on the development of active optical structures, laser processing strategies and the fabrication of practical testing prototypes.
Luminescent devices based on rare earth containing thin films deposited by plasma technology (LUMEN)
16-05-2013 / 15-05-2016
Research Head: Angel Barranco Quero
Financial Source: Junta de Andalucía
Code: P11-TEP-8067 (Proyecto de Excelencia Motriz)
Research Team: Agustín R. González-Elipe, Juan Pedro Espinós, Richard Lambert, Juan Carlos González-González, Francisco J. García García, Victor J. Rico Gavira, Jorge Gil Rostra, Lola González García, F. Javier Ferrer (CNA), Fabián Frutos Rayego
The objective of the LUMEN project is the development of luminescent devices incorporating as active layers rare earth containing thin films deposited by plasma CVD. The thin films will be deposited by novel synthetic approaches that combined classic approaches as magnetron sputtering and plasma CVD with the sublimation of functional molecules. This methodology is very effective to introduce a controlled amount of functional elements (i.e., rare earth cations of functional organic groups) in the growing film. Due to the full compatibility of the proposed methodology with optoelectronics processes the active layers will be directly incorporated in photonic structures as Bragg reflectors and photonic crystals to fabricate prototype devices. Thus, the LUMEN projects start with the development of new materials but also intend to study the functionality of devices that integrates these novel materials in real life conditions. These devices are intelligent label structures, up-converters and ion detectors.
Preparation of technically interesting nanocomposites by mechanochemistry
16-05-2013 / 31-03-2018
Research Head: Luis A. Pérez Maqueda
Financial Source: Junta de Andalucía
Code: P11-TEP-7858 (Proyecto de Excelencia)
Research Team: José Manuel Criado Luque, María Jesús Diánes Millán, José Luís Pérez Rodríguez, Juan Poyato Ferrera, Pedro Enrique Sánchez Jiménez, Antonio Perejón Pazo
Nanocomposites are of the most academic and technical interest. Those materials consist of two or more different phases being the dimension of one of the phases smaller than 100 nm. Thus, those materials have outstanding properties as compared with conventional ones. In this project, mechanochemistry is proposed for the preparation of different nanocomposites. This preparation procedure is sustainable from the environmental point of view and easy to scale-up. In the frame of the project, a unique high energy planetary ball mill will be developed in collaboration with the MC2 enterprise. Moreover, a study of the forces as a function of the milling conditions will be performed in order to get a better understanding of the processes involved in the mechanochemical reactions. Two types of nanocomposites will be prepared: a) copper reinforced nanocomposites and b) partially and totally stabilized zirconia. In the latter case, powders will be sintered using a kind of field assisted sintering procedure. It is expected a reduction in the sintering temperature of the zirconia. The kinetics of the sintering process with and without electric field will be performed within the project using an new dilameter that will be constructed for this purpose.
The obtention of fatty polyhydroxyalcanoate (PHA) bioplastics from peels residues of commercial fruits
16-05-2013 / 15-05-2016
Research Head: José Jesús Benítez Jiménez
Financial Source: Junta de Andalucía
Code: P11-TEP-7418 (Proyecto de Excelencia)
Research Team: Antonio Heredia Bayona, Miguel Angel San Miguel Barrera, Jaime Oviedo López, J. Alejandro Heredia Guerrero, Santiago Domínguez Meister, Daniel Aguilera Puerto, Francisco Javier Navas Martos, José Manuel de la Torre Ramírez
The main objective of this project is to evaluate the feasibility of scaling up a procedure to obtain fatty polyhydroxyalcanoate (PHA) bioplastics from a low-cost and abundant source like peels residues of commercial fruits. The strength of the proposal relies on the introduction of a new non-toxic and fully biodegradable polymeric material as a substitute for environmental-hostile petroleum-based plastics. The overall sustainability is extended to the use of a low-impact synthetic route and to the processing of a plant residue rather than crops intended for human or cattle feeding. The project is considered of additional interest in regions with an agricultural based economy like Andalusia and with an important environmental impact arising from the greenhouse activity. The proposal also covers the study of new and more specific applications of such bio-based fatty polyhydroxyalcanoates.
CO2 Utilization for synthesis gas obtaining: Use of structured catalysts
01-02-2013 / 31-01-2017
Research Head: Miguel Angel Centeno Gallego
Financial Source: Junta de Andalucía
Code: P11-TEP-8196 (Proyecto de Excelencia)
Research Team: Svetlana Ivanova, Maria Isabel Domínguez Leal, José Antonio Odriozola Gordón, Tomás Ramírez Reina, Francisca Romero Sarria
Nowadays, the concentration of greenhouse gases, GHG, in the atmosphere, specifically CO2, is continuously increasing. In order to avoid or minimize such increment, three different strategies must be applied: i) the improvement of the efficiency on the energy production systems, ii) the lower utilisation of fossil fuels and iii) the implementation of processes of CO2 capture and sequestration. Since the economic growth and the life quality must be maintained, particularly in the less developed countries, the last item is the most favourable approximation for a sustainable development.
In the present Project, the utilisation of CO2 as raw material for natural gas reforming is proposed as preliminary step in the production of synthetic liquid fuels.By using conventional technologies, this proposal is economically viable only exploiting natural gas reserves. However, microchanel technology allows the discontinuous production of the synthetic fuels, with a high and flexible production in an economic way. Our project is focussed in the design, characterization and testing of active, selective and stable catalysts in the steam-dry reforming of methane, SDRM:
CO2 + 3CH4 + 2H2O → 4CO + 8H2
The final step of the project is the structuration of the selected catalysts in metallic micromonoliths with parallel channels as an intermediate step for their future implementation on microchannel reactors.
Development of novel materials and processes for the generation and use of hydrogen mainly in portable applications
01-01-2013 / 31-12-2015
Research Head: Asunción Fernández Camacho
Financial Source: Ministerio de Economía y Competitividad
Code: CTQ2012-32519
Research Team: Gisela Arzac, Jaime Caballero, Lionel Cervera, Vanda Fortio, Carlos Negrete, Dirk Hufschmidt, Cristina Rojas Ruiz, Roland Schierholz
Hydrogen as a vector of transport and storage of energy is a very attractive candidate in the context of increased use of renewable and clean energies. This project will address the study of the different processes that lead to the final configuration of an integrated systems for hydrogen generation and use mainly in portable applications (and potentially scalable for stationary applications). In particular, work will be carried out in this project in the following lines:
a) Research on new lightweight compounds for use in hydrogen generation processes on a small scale by chemical routes (hydrolysis). Typically hydrolysis reactions of borohydrides (i.e. NaBH4) and compounds like ammonia borane, hydrazine borane or hydrazine. This line includes the development of catalysts at the nanoscale using wet chemical methods for their synthesis: Metal-metalloid nanostructures (i.e. Co-B, Co-B-P and similar ones) and bimetallic catalysts (including or not metalloid) of low cost which potentiate synergistic effects (i.e. CoRu, NiPt or Co-Ru-B). The topic also includes the development of portable reactors for these processes and the development of new substrates and monoliths, studies of adherence and durability of the catalyst.
b) Research on new host-guest systems containing hydrogen for reversible storage (loading / unloading). Mainly porous supports (host) like the so called "nanoscaffolds" (based on C or BN) infiltrated with borohydrides materials (guest) (i.e. titanium borohydride) typically used for reversible hydrogen storage. These new materials must present improved charging and de-charging kinetics.
c) Studies of coupling a hydrogen generator system with a low cost fuel cell. Typically a continuous reactor for the hydrolysis of NaBH4 with Co-B catalyst for providing H2 at constant flow rate conditions to directly feed a PEM fuel cell of 60 W.
d) Fundamental studies for the development of catalysts and supports for the controlled combustion of hydrogen. It's a new line in the research group based on wet chemical preparation of noble metal nanoparticle catalysts on commercial porous ceramic supports (i.e. SiC). The line also includes the design of a reactor for laboratory-scale study of heat production by controlled combustion of hydrogen.
e) Development of sputtering technology ("magnetron sputtering") for the preparation of catalysts and nano-structures on various substrates for use in the processes developed in the previous sections. The group has extensive experience in this technology to be applied in novel ways in this project leading to a great versatility regarding nanostructure, composition and addition of additives to improve catalytic activity, durability and selectivity of catalysts.
f) Microstructural and chemical characterization of new materials and catalysts developed in the project. We are dealing typically with materials of controlled nanostructure where modern nanoscopic techniques will play a key role in the custom manufacturing of these materials
Valorization of Non-conventional gas: microchannel reactors in GTL
01-01-2013 / 31-12-2015
Research Head: José Antonio Odriozola Gordón
Financial Source: Ministerio de Economía y Competitividad
Code: ENE2012-37431-C03-01
Research Team: Svetlana Ivanova, Anna Dimitrova Penkova, Tomás Ramírez Reina, Sandra Palma del Valle, Ara Muñoz Murillo, María Isabel Domínguez Leal, Francisca Romero Sarria
Apart from the large reserves, natural gas is present in a wide variety of sources that can be grouped as non-conventional gas, including non-conventional natural gas confined in low-permeability geological deposits, associated gas, biogas produced by anaerobic digestion of residues and product gas a result of biomass and tar gasification. Most of them are, in general, far from marketplaces and transport infrastructures, present in small or medium fields that does not allow large-scale GTL plants and, as in the associated gas in oil fields contribute to increase GHG. These gases have a similar composition, they mainly contain methane and carbon dioxide, the later may reach 40% by volume as in some off-shore oild fields and biogas produced by digestion of crop residues. Recent trends in the use of syngas are dominated by the conversion of inexpensive remote natural gas into liquid fuels (“gas to liquids” or GTL) forecasts the use of non-conventional gas in compact syngas units for GTL processes resulting in liquid fuels of easier storage and transportation having direct aplication for transport.
GTL technology developed for microchannel reactors notably increases the production yield of syngas and Fischer-Tropsch synthesis (FTS) units on running the reaction under high space velocities and improving temperature control, therefore enhancing selectivity and process safety. Modularity, which is based on unit replication, simplifies the scaling-up and allows an easier adjust to small and medium size production units.
In this Project, we aim at developing microchannel technologies for GTL using CH4-CO2 mixtures that simulate non-conventional gas resources. Our previous studies on microchannel reactor technology will be put forward to adapt to the elevated temperatures and pressures required for the GTL process. This will allow validation of the bonding techniques as well as improve materials selection to fit these drastic requirements.
New catalysts adapted to the GTL process in microchannels will be developed for steam and dry reforming of methane as well as for the partial oxidation of methane and the FTS. These catalysts must be active, selective and stable under reaction conditions and will be tested in powder, in structured form (micromonoliths) and in microchannels units. For them kinetic equations will be developed and the built microchannel reactor will be modeled and simulated.
Innovative SOFC Architecture based on Triode Operation
01-09-2012 / 29-02-2016
Research Head: Agustín R. González-Elipe
Financial Source: Unión Europea
Code: FCH-JU-2011-1
Research Team: Francisco Yubero Valencia, Juan Pedro Espinós Manzorro, Angel Barranco Quero, Richard Lambert, Victor J. Rico, Ana Borrás Martos, José Cotrino, Jorge Gil, Pedro Castillero, Francisco J. García, Alberto Palmero
The development of Solid Oxide Fuel Cells (SOFCs) operating on hydrocarbon fuels (natural gas, biofuel,LPG) is the key to their short to medium term broad commercialization. The development of direct HC SOFCs still meets lot of challenges and problems arising from the fact that the anode materials operate under severe conditions leading to low activity towards reforming and oxidation reactions, fast deactivation due to carbon formation and instability due to the presence of sulphur compounds. Although research on these issues is intensive, no major technological breakthroughs have been so far with respect to robust operation, sufficient lifetime and competitive cost.
T-CELL proposes a novel electrochemical approach aiming at tackling these problems by a comprehensive effort to define, explore, characterize, develop and realize a radically new triode approach to SOFC technology means of an integrated approach based both on materials development and on the deployment of an innovative cell design that permits the effective control of electrocatalytic activity under steam or dry reforming conditions.
The novelty of the proposed work lies in the pioneering effort to apply Ni-modified materials electrodes of proven advanced tolerance, as anodic electrodes in SOFCs and in the exploitation of our novel triode SOFC concept which introduces a new controllable variable into fuel cell operation.
In order to provide a proof of concept of the stackability of triode cells, a triode SOFC stack consisting of at least 4 repeating units will be developed and its performance will be evaluated under methane and steam co-feed, in presence of a small concentration of sulphur compound.
Tribological nanostructured films for operation under vacuum and variable environment
01-01-2012 / 31-12-2014
Research Head: Juan Carlos Sánchez López
Financial Source: Ministerio de Ciencia e Innovación
Code: MAT2011-29074-C02-01
Research Team: Cristina Rojas Ruiz, Carlos López Cartes (US), Francisco Javier Pérez Trujillo (UCM)
Control of the Optical Emission and Absorption properties of Nanomaterials Integrated in Multifunctional Porous Photonic Structures
01-01-2012 / 31-12-2014
Research Head: Hernán R. Míguez García
Financial Source: Ministerio de Ciencia e Innovación
Code: MAT2011-23593
Research Team: Nuria Nuñez Alvarez, Mauricio Calvo Roggiani, Carmen López López, Sonia Rodríguez Liviano, Manuel Ocaña Jurado, Silvia Colodrero Pérez, José Raúl Castro Smirnov
In this project the modifications of both optical emission and absorption of nano-materials of different sort (rare earth doped nanoparticles, semiconductor quantum dots, metallic nanoparticles, and films of organic dyes of nanometer dimensions) that occur when they are embedded in different types of photonic structures will be investigated. Both fundamental and applied aspects of the subject will be analysed. Efforts will be mainly focused on materials of current technological interest for solar cells, sensors and light emitting devices. From the applied point of view, this project finds its motivation in the possibility that photonic structures offer of modifying absorption and emission processes in a controlled manner so that they can be inhibited or amplified depending on the specific goal pursued. Particularly, we seek to put into practice these concepts to generate new designs of more efficient solar cells, capable of harvesting a larger amount of the incident radiation, and in the development of films for sensing devices responsive to modifications of different kind, such as presence of targeted molecules, variations of ambient gas pressure, etc... Also, more efficient or controlled light extraction from light emitting devices is sought after. The development of small prototype devices to prove the novel concepts under research is also an objective of this grant proposal.
In its more fundamental aspect, our project aims at deepening our knowledge of the interaction between light and matter in systems in which there exists a strong dispersion and anisotropy of the dielectric constant, and in which it is possible to attain very low photon propagation speeds. For this analysis, we will employ different types of porous photonic structures, such as one-dimensional and three-dimensional photonic crystals, as well as disordered assemblies of particles, as hosts in which a wide range of organic and inorganic nanomaterials will be integrated in different configurations and whose absorption and emission will be experimentally and theoretically studied.
Although this project has a fundamental character due to the nature of the prepara-tion techniques and complex optical properties we seek to analyze, it is our aim to continue generating and transferring intellectual property based on the novel concepts, properties and designs which are the subject of our research.
Development of nanostructured catalytic systems prepared by sol-gel and fotoassisted deposition (PAD) methods for energy and environmental applications
01-01-2012 / 31-12-2014
Research Head: Alfonso Caballero Martínez
Financial Source: Ministerio de Ciencie e Innovación
Code: ENE2011-24412
Research Team: Gerardo Colón Ibáñez, Juan Pedro Holgado Vázquez, Sergio Obregón Alfaro, Rosa María Pereñiguez Rodríguez, Fátima Ternero Fernández
In the present project we propose the development of a series of nanostructured catalysts based on transition metals such as Ni, Cu, Au or Pd deposited in active supports (TiO2, CeO2, WO3, Fe2O3 and mesoporous supportslike SBA-15 doped with titania and ceria). Conventional methods of preparation will be used (impregnation, deposition-precipitation, etc.), along with procedures of synthesis of more recent development, like sol-gel and, very specially, the denominated Photochemical Assisted Deposition (PAD). In this way, we expect to control at the nanometric scale the size of the metallic and/or bimetallic particle, along with the interaction between the metal and support surface. In the case of the PAD method, one of the primary targets of the project is the study and optimization of the different parameters affecting the deposition process. So that, besides the control of the metallic particle size from diameters around 15nm to atomic dispersed systems on active supports like ceria or titania, it would allow us to design the distribution of metals in bimetallic particles, making use of consecutive and/or simultaneous controlled processes of fotodeposition of metals. Using this methodology, we will try to obtain metallic distributions of different kinds: core-shell, alloys, etc., which as it is well-known, can strongly affect the catalytic performances. These benefits will be verified in different catalytic reactions of energetic and/or environmental interest, both in gas and liquid phase. Thus, the systems based on nickel and gold will be used in the steam and dry reforming reactions of methane and the selective oxidation of CO (Preferential Oxidation of CO, PROX), respectively. The bimetallic catalytic systems based on palladium and palladium-gold will be used for the optimization of the reaction of direct synthesis of hydrogen peroxide from hydrogen and oxygen, made in liquid phase at high pressure. The correlation between the physical-chemistry state and the reactivity of the catalytic systems will allow us to clarify fundamental aspects of the mechanisms of the proposed heterogeneous reactions
Development of nanostructured protective coatings for extreme environmental conditions (NANOPROTEXT)
01-01-2012 / 31-12-2014
Research Head: Juan Carlos Sánchez López
Financial Source: Ministerio de Ciencia e Innovación
Code: MAT2011-29074-C02-01
Research Team: T. Cristina Rojas Ruiz; Francisco Javier Pérez Trujillo;Maria del Pilar Hierro de Bengoa;Germán Alcalá Penades; Maria Sonia Mato Díaz; Marta Brizuela; Pablo Corengia; José Luis Viviente; Alberto García;Daniel González
In many industrial operations, the machines or tool components in contact are submitted to severe conditions of load, friction, temperature or variable atmosphere. The research efforts are directed towards the development of new multiphase coatings capable to increase their performance by protection of the surface against wear and oxidation that cause failure mechanisms. By appropriate control of the size and distribution of phases, chemical composition and microstructure in the nanometric regime it is possible to obtain multifunctionality as low friction, hardness and thermal stability. To achieve excel in this purpose it is necessary to correlate the macroscopic properties of these coated surfaces (mechanical, tribological, oxidation resistance) with these basic phenomena.
In this project, three types of nanostructured coatings will be prepared using a magnetron sputtering process for protection in running operations under extreme or singular conditions (pressure, temperature, oxidant atmospheres, vacuum, etc.). The chosen systems are constituted by crystals of hard materials (nitrides or carbides) in combination with a second element or phase that improves the practical performance. Thus, nanocomposite coatings consisting of WC nanocrystals dispersed in an amorphous dichalcogenide phase (WS2 or WSe2) are proposed as solid lubricant coatings to run under high vacuum conditions useful for spatial applications or inert environments. In the second case, Y or Zr will be tested as dopant elements in CrAlN coatings with the aim of increasing the corrosion and oxidation resistance and tribological behaviour useful for many industrial fields (machining tools, metallurgy, aeronautic, automotive, etc…). Finally, hard and transparent nanocomposite coatings based on the Al-Si-N system are suggested as protective coatings for optical systems.
In all cases, the project comprises their synthesis, chemical and structural characterization, and validation in tribological and oxidation under extreme condition tests that simulate the final operation conditions. In the case of the hard and transparent coatings, their optical properties will be also analysed. The establishment of the relationships between microstructure and measured properties will be an essential objective, since it enables the better understanding of the action mechanisms, and thus, the optimisation of such nanostructured multifunctional systems for an improved technological benefit.
Fatty hydroxyacids molecular interactions as model for biomimetic polyester design
01-01-2012 / 31-12-2014
Research Head: José Jesús Benítez Jiménez
Financial Source: Ministerio de Ciencia e Innovación
Code: CTQ2011-24299
Research Team: Alejandro Heredia Guerrero, Miguel Angel San Mibuel Barrera, Jaime Oviedo López, Miguel Salmerón Batalle
The objective of this Project is to study and characterize the specific interactions between fatty carboxylic acids molecules arising from selective hydroxylation of the alkyl chain. To address this issue, molecular self-assembled systems showing a low interaction with an atomically flat support are proposed as models. The use of low binding energy supports is to ensure the packing structure to be mainly driven by the molecule to molecule interactions rather than the molecule to substrate adsorption. These self-assembled systems will be characterized by scanning probe microscopies such as AFM and STM and infrared spectroscopy. Results will be complemented with molecular dynamics atomistic simulations. Basic information obtained from self-assembled models will be used to design the in-vitro chemical synthesis of cutin mimetic polyesters. Cutin is a non toxic, fully biodegradable barrier biopolymer present at the skin of fruits, leaves and non lignified stems of higher plants. Physical (mechanical, water permeability, ionic transport, etc…) and chemical (ester yield, controlled chemical degradation rate, etc…) properties of synthetic polyesters will be determined. Material features will be related with both, the main structure arising from the ester bonds formation and the secondary network resulting from hydrogen bonding between spare non reacted hydroxyl groups. Structure-function patterns will be used to redesign the synthesis route to obtain polymeric esters with tailored properties. To achieve this goal, both the primary and secondary structural networks will be manipulated. In the first case non hydroxylated molecules will be used to prevent ester bonding propagation. To modify hydrogen bonding crosslinking, additives with selected hydroxylation (primary or secondary) will be employed. The final motivation of this research is to explore the applicability of such mimetic polyester as substitutes for the highly contaminant hydrocarbon based plastics.
Mechanochemical desing of structural materials for high-temperature technological applications
01-01-2012 / 31-12-2014
Research Head: Francisco José Gotor Martínez
Financial Source: Ministerio de Ciencia e Innovación
Code: MAT2011-22981
Research Team: M. Jesús Sayagués de Vega, Concepción Real Pérez, M. Dolores Alcalá González, Pedro José Sánchez Soto, José Manuel Córdoba Gallego, Ernesto Chicardi Augusto
Carbides, nitrides and borides of transition metals are essential components of a large number of composite materials used for structural and protective applications at high temperature because they show an excellent combination of physical and chemical properties, which confers good mechanical strength, and wear, oxidation and corrosion resistances. The materials based on these refractory compounds are designed by employing multiphasic systems, due to the high multi-functionality that are required and the inability to achieve the intended properties from a single phase material.
During the processing of these materials is common to observe important compositional gradients and interactions between the different constituent phases that hinder achieving the desired properties. In this project, we intend to undertake a new design for this type of material of incorporating most of its key components such as complex solid solutions. This will reduce the final number of phases in the material and obtain greater assurance of success with the preset properties for technological applications. To this end, we propose a new synthesis route based on the mechanochemical process called as mechanically-induced self-sustaining reaction (MSR). Our research group has shown that this method allows obtaining solid solutions belonging to M-B-C-N systems with a high control of the stoichiometry. The main objective of this project is to incorporate the method MSR to the methodology used for the development of materials consisting of solid solutions that can be used in high temperature applications. It is intended to adequately characterize the properties of the developed materials and to compare them with those made using the methods so far employed.
Photo-active materials to exploit solar energy for photocatalytic processes of environmental interest
1-01-2012 / 31-12-2012
Research Head: José Antonio Navío Santos
Financial Source: Ministerio de Ciencia e Innovación
Code: CTQ2011-26617-C03-02
Research Team: Mª del Carmen Hidalgo López, Manuel Macías Azaña, Julie J. Murcia Mesa; Sebastián Murcia López
The heterogeneous photocatalysis has extensively shown its potential for detoxification and disinfection of aqueous and gaseous media. However, technological development has been very limited due to a number of difficulties that can be grouped into two main groups:
1. Difficulties inseparating the catalyst from the reacting medium for recovery and reuse once completed the process.
2. Poor performance of the process, which uses only a very small percentage of photons useful, and these are only a small part of the natural spectrum.
Our proposal is composed by three sub-projects led by three groups which combine extensive experience in: Synthesis, modification and characterization of photocatalytic materials (mainly the group at the University of Seville), Preparation and characterization of metal oxide thin films on different substrates (mainly the group from CIEMAT) and Modification, spectroscopic characterization of active centers and photoreactivity studies in aqueous and gaseous phase (mainly the group from the ULPGC).
Based onthe experience gained and the main trends in the development of heterogeneous photocatalysis, our consortium proposal has a central objective: Synthesize materials based on TiO2, SnO2, ZnO and ternary materials such as bismuth titanate (BITs), in powder form with nanometric size, with high photocatalytic activity and its support on suitable substrates (glass, membrane, metal sheets, etc.) coated with thin films of different metal oxides to facilitate the fixation of powder particles and/or acting as seed for the formation or crystallization of these particles in order to use these systems efficiently in photocatalytic detoxification processes in aqueous phase and gas phase.
Polymer-Inorganic Flexible Nanostructured Films for the Control of Light (POLIGHT)
01-01-2012 / 30-11-2017
Research Head: Hernán R. Míguez García
Financial Source: Unión Europea
Code: (FP7/2007-2013)/ERC Grant Agreement No. 307081 (POLIGHT)
The POLIGHT project will focus on the integration of a series of inorganic nanostruc-tured materials possessing photonic or combined photonic and plasmonic properties into polymeric films, providing a significant advance with respect to current state of the art in flexible photonics. These highly adaptable films could act either as passive UV-Vis-NIR selective frequency mirrors or filters, or as matrices for light absorbing or optically active species capable of tailoring their optical response. The goal of this project is two-fold. In one aspect, the aim is to fill a currently existing hole in the field of materials for radiation protection, which is the absence of highly flexible and adaptable films in which selected ranges of the electromagnetic spectrum wavelengths can be sharply blocked or allowed to pass depending on the different foreseen applications. In another, the POLIGHT project seeks to go one step beyond in the integration of absorbing and emitting nanomaterials into simple flexible polymeric matrices by including hierarchically structured photonic lattices that provide fine tuning of the optical properties of these hybrid ensembles. This will be achieved by means of enhanced matter-radiation interactions that result from field localization effects at specific resonant modes. The opportunity arises as a result of the recent development of a series of robust inorganic photonic structures that present interconnected porous networks susceptible of hosting polymers and thus inheriting their mechanical properties.
Processing of advanced ceramics from polymeric precursors by smart temperature methods
01-01-2012 / 31-12-2014
Research Head: Luis Pérez Maqueda
Financial Source: Ministerio de Ciencia e Innovación
Code: CTQ2011-27626
Research Team: Maria Jesús Diánez Millán, José Manuel Criado Luque, Pedro E. Sánchez Jiménez, Antonio Perejón Pazo
Ceramic materials prepared from polymer precursors, known as polymer-derived ceramics (PDC) are a subject of the most interest. These materials are prepared from a polymer that is first cured and then ceramified, usually by thermal treatment at relatively low temperature if compared with those needed in conventional ceramic processing from ceramic powders. Thus, the final product is directly obtained in a near-net shape process. These materials have very interesting electrical, thermomecanical and oxidation resistance properties. Thus, a number of applications from nanotechnology to aeronautics have been proposed. Nevertheless, a significant limitation of the use of these materials is is related with the ceramification process of the preceramic piece. During this thermal conversion, some defects, such as cracks, appear in the pieces. In this project, we propose the use of smart temperature controlled methods for the processing of the preceramic polymeric precursors. In previous studies, we have shown the advantages of this methodology for controlling the structure and microstructure of the products prepared by thermal transformation of precursors. In addition, this methodology is also useful for kinetic studies of solid state reactions. In the present project, we expect to obtain defect free PDC materials and to study the influence of the preparation conditions on the nanostructure of the products and get new insights in polymer to ceramic conversion process, paying special attention to the study of the kinetics of the involved processes. The so-obtained products will be characterized in terms of their nanostructure and properties, in particular piezoresistivity, lithium insertion capacity and oxidation resistance.
Advanced laboratory for the nano-analysis of novel functional materials (AL-NANOFUNC)
01-10-2011 / 30-03-2015
Research Head: María Asunción Fernández Camacho
Financial Source: Unión Europea
Code: REGPOT-CT-2011-285895
Research Team: T. Cristina Rojas, M.Carmen Jiménez, Gisela Arzac, Olga Montes, Inmaculada Rosa, Rafael Alvarez, Vanda Godinho, Juan Carlos Sánchez-López, Hernán Míguez, Agustín R. González-Elipe, Manuel Ocaña, M. Jesús Sayagués, Lionel Cervera, Roland Schierholz, Salah Rouillon, Lucia Castillo, Rocío García, Carlos García-Negrete, Jaime Caballero
The AL-NANOFUNC project has been designed to install and fully develop at the Materials Science Institute of Seville (ICMS, CSIC-Univ.Seville, Spain) an advanced laboratory for the Nano-analysis of novel functional materials. Advanced Nanoscopy facilities, based on latest generation electron microscopy equipments, will be devoted to breakthrough research in specific topics of high interest: i) Nanomaterials for sustainable energy applications; ii) protective and multifunctional thin film and nanostructured coatings; iii) nanostructured photonic materials and sensors. To take the ICMS laboratories to a leading position that is competitive in a world-wide scenario, the AL-NANOFUNC project is contemplated to up-grade the actual research potential in several directions: i) improve equipment capabilities regarding the Analytical High Resolution Electron Microscopy facilities; ii) improve the impact and excellence of basic research through hiring of experienced researchers and transnational exchange with the reference centers in Europe; iii) develop and improve the innovation potential of the ICMS’s research by opening the new facilities to companies and stakeholders; iv) organize workshops and conferences, dissemination and take-up activities to improve research visibility. Close collaborations with reference centers and companies in Liège (Belgium), Graz (Austria), Jülich (Germany), Oxford (England), Cambridge (England), Dübendorf (Switzerland) and Rabat (Morocco), as well as with laboratories at Andalucian Universities, are foreseen in this project. Five companies in Andalusia will also collaborate in close synergies to promote the long-term strategic lines of interest for the region in the natural and artificial stone products and solar and renowable energy sectors.
Nanostructured films for operating under vacuum
01-10-2011 / 31-12-2011
Research Head: Juan Carlos Sánchez López
Financial Source: Ministerio de Ciencia e Innovación
Code: MAT2010-21597-C02-01
Research Team: T. Cristina Rojas Ruiz, Santiago Domínguez Meister
In this project, nanostructured coatings will be prepared using a magnetron sputtering process for lubrication of mechanical components used in aerospace applications. These materials must provide wear protection and low friction when operating in ambient air or vacuum environment. The chosen systems to obtain this compromise are constituted by WC nanocrystals dispersed in an amorphous dichalchogenide phase (WS2 or WSe2). These solid lubricant coatings are proposed to enhance the wear resistance, mechanical strength and oxidation resistance in comparison to their conventional MoS2 or DLC coatings for this kind of applications.
Development of Nanostructured Ceramic Coatings and Scaffolds for Bone Regeneration (BIOCEREG)
06-07-2011 / 05-06-2016
Research Head: María Aránzazu Díaz Cuenca
Financial Source: Junta de Andalucía
Code: CTS-661
Research Team: M. Lourdes Ramiro Gutiérrez, Sara Borrego González
The aim of this Project is to advance in the development of new biomaterials with im-proved bioactivity for their application in bone repair and regeneration. The goal is the prepa-ration of new coatings and scaffolds of ceramic materials using laser processing techniques from nanostructured ceramic particulates in the SiO2-CaO-P2O5 system which will be synthe-sised at the ICMS. The hypothesis is the compositional properties and the textural parameters of the particulates in combination with the laser source have potential for processing depositions with controlled macro-nanostructure. It is programmed to prepare two types of prototype pieces: i) Titanium metallic substrates with bioactive ceramic coatings and ii) monolith scaffolds of bioactive ceramic with controlled geometry. There are two milestones to highlight. The first one is the fabrication of prototype pieces (coatings and scaffolds) with reproducibility, homogeneity, micro-nanostructural features, and surface and mechanical properties requirements. A second milestone will be the evaluation of their in vitro an in vivo biological properties. The achievement of both mentioned milestones will lead to the final biomaterial prototype. Bone regeneration biologists and orthopaedic surgeons will study the bioactivity and biocompatibility of the coatings on titanium substrates provided by Synthes which is a leader Company in orthopaedic trauma devices for internal and external fixation and is included in the proposal as EPO. The application of the laser processing to the SiO2-CaO-P2O5 nanostructured ceramic materials is completely new and we believe that it could be optimised for obtaining coatings and reticulated scaffolds while keeping their nanostructural features. The Project integrates material scientist, laser engineers, biologists and orthopaedic surgeons. We believe that this multidisciplinary approach with work in the i) synthesis, processing and characterisation of materials, ii) regeneration biology and tissue engineering and iii) medical practise could achieve results with potential to be transferred to the industry to promote the orthopaedic products to improve Andalusian bone repair and regeneration therapies.
Development of new industrial processes based on catalytic systems for Sustainable production of base compounds of fragrances and aromas
04-05-2011 / 31-12-2014
Research Head: Juan Pedro Holgado Vázquez
Financial Source: Ministerio de Economía y Competitividad
Code: IPT-2011-1553-420000
Research Team: Alfonso Caballero Martínez, Víctor Manuel González de la Cruz, Rosa Pereñíguez Rodríguez, Gerardo Colón Ibáñez
Nowadays, most of the industrial processes used for transformations of many com-pounds used in the field of fragrances and aromas have low yields, and generate a lot of environmentally noxious products, being necessary to accomplish several stages of segregation and treatment during the process of production of these chemicals. Most of these processes are done by reduction or oxidation reactions using stoichiometric compounds, or are based in homogeneous catalysis, that present associated hitches associated with corrosion, recovery of the catalysts from reaction media and its regeneration for its possible recycle. In this “environmentally friendly” context, there is a growing interest in the use of oxidants less contaminants, such as molecular oxygen or hydrogen peroxide, and the integration of these oxidants into heterogeneous catalysis processes. Obviously, one of the big challenges for catalytic systems is to maximize the yield (conversion times selectivity), in order to reduce the consumption of reactants (raw material), and minimize the separation and elimination of undesired sub-products obtained as consequence of process inefficacy. In these type of reactions (with mainly organic products, many from natural sources), it is not, as a general rule, difficult to obtain a high conversion, but as the starting materials present many functionalities and/or points susceptible to be oxidized, the main challenge is to obtain a (very) high selectivity, in many cases even at enantiomer level. In this project, we have selected processes and reactions with a direct interest in the food and cosmetic industry, with the scope to develop processes, at industrial scale, based on heterogeneous catalysts to obtain compounds with high added value in the aromas and fragrances fields, such as the production of l-carvone from catalytic oxidation of d-limonene.
Sun and vision for the present thermal energy. SOLVENTA
4-05-2011 / 31-12-2014
Research Head: Agustín R. González-Elipe
Financial Source: Ministerio de Ciencia e Innovación
Code: Proyecto INNPACTO - IPT-2011-1425-920000
Research Team: Francisco Yubero Valencia, Juan Pedro Espinós Manzorro, Angel Barranco Quero, Victor J. Rico, Ana Borrás Martos, José Cotrino, Jorge Gil, Pedro Castillero, Fran J. García
This Project aims at the development of a series of equipment and devices to monitor the working conditions of solar thermal plants based on light concentration with cylindrical parabolic mirrors. The role of ICMS in this project focusses on the application of plasma technology systems and the development of thin films able to determine the working conditions of these facilities.
Development of carbon-based composites for biomedical applications
15-03-2011 / 15-03-2014
Research Head: Juan Carlos Sánchez López
Financial Source: Junta de Andalucía
Code: P10-TEP 06782
Research Team: T. Cristina Rojas, Carlos López Cartes, David Abad, Vanda Godinho, Santiago Domínguez, Inmaculada Rosa
This project pursues the development of carbon-based coatings including the tailored synthesis, characterization, evaluation in wear tests and biocompatibility study for the application in artificial implants. The control of the carbon chemical bonding (sp2/sp3) and the chemical composition, including metals as (Ag, Ti) or other elements (B, N, O) will enable to tune the mechanical and tribological properties (hardness, friction and wear resistance) with the aim of improving the final performance. To achieve this goal, the use of magnetron sputtering technique is envisaged to deposit advanced coatings under different synthesis conditions. Next, these carbon composites will be evaluated comparatively in friction and wear tests that simulate the conditions that these materials will face in the final application. In this way, it will be possible to establish the correlation between the observed behavior and chemical and structural characteristics of the prepared layers in cell adhesion tests, cytotoxicity and antibacterial activity. This complete characterization will provide an excellent overview of the possibilities of technological transfer of these advanced materials to the biomedicine.
Process-control in plasmas for the synthesis of nanostructured thin films (PLASMATER)
15-03-2011 / 14-03-2014
Research Head: Alberto Palmero Acebedo
Financial Source: Junta de Andalucía
Code: P09-FQM-6900
Research Team: José Cotrino Bautista, Ana Borrás Martos, Francisco Yubero Valencia, Rafael Alvarez Molina, Juan Carlos González González, Carmen López Santos
Project PLASMATER aims at developing new plasma-based procedures to control the nanostructure, porosity and morphology of deposited thin films, and optimize the material functionalities and applications. From an experimental point of view, plasma-assisted thin film deposition techniques make use of various quantities to define the deposition conditions, such as the electromagnetic power, pressure in the reactor, etc. These quantities controls the plasma properties, which at the same time conditions the growth mechanism of the films. The complexity of the relation between experimentally controllable quantities and growth processes has produced the existence of empirical relations between experimental conditions and final film structure and composition, whose justification from a fundamental point of view is unclear. In PLASMATER we propose to analyze three related aspects of the deposition of TiO2 and ZnO thin films assisted by plasmas: i) complete diagnosis of the plasma bulk and sheath in connection with the material microstructure, ii) functionality of the material, and iii) the de-velopment of predictive numerical codes that calculate the final film microstructure as a func-tion of experimentally controllable quantities. This last part is of relevance because to our knowledge, i) it is the first time in the literature the deposition is fully characterized from a fundamental point of view, ii) this knowledge can be applied to suggest modifications in the deposition reactor in order to enhance different structural properties of the films. In order to carry out the PLASMATER project, we aim at following at mixed theoretical and experimental strategy in order to interactively develop numerical codes of the thin film growth in multiple conditions. All the spatial scales involved in the description must be studied, from the plasma bulk itself (typically of few tens cm), the plasma sheath (below 1 mm), and the surface of the material (tens nm). Advanced diagnosis techniques will be employed to understand the plasma behavior and the film growth. Finally, PLASMATER will focus on the experimental conditions that lead to an optimized performance of the studied materials for advance applications in technology and industry.
New Bi3+ based photocatalysts highly active in the visible
11-03-2011 / 31-03- 2015
Research Head: Gerardo Colon Ibáñez
Financial Source: Junta de Andalucía
Code: P09-FQM-4570
Research Team: M. Carmen Hidalgo López, José Antonio Navío Santos, Manuel Macías Azaña, Sebastián Murcia López
The main objective of this project is the development of a new generation of nanostructured materials alternative to TiO2 with high photoactivity in the visible region that could be efficiently used in liquid or gaseous effluent treatment. The present project intent to develop new heterogeneous nanocatalytic systems based on Bi3+ (Bi2WO4, Bi2MoO6, BiVO4, Bi3O4Cl, CaBi2O4, PbBi2Nb2O9,…) exhibiting appropriated optoelectronic properties for the solar light use in the visible range (Solar Photocatalysis). Moreover, from the point of view of the photoinduced charge carriers diffusion and transfer, the improved physicochemical properties would optimize the photocatalytic process.
Environmentally friendly processing of ceramics and glass (CERAMGLASS)
1-01-2011 / 31-12-2014
Research Head: Xermán F. de la Fuente Leis
Financial Source: Ministerio de Economía y Competitividad
Code: LIFE11 ENV/ES/560
Research Team: ICMS: Agustín R. González-Elipe, Victor J. Rico, Angel Barranco Quero, Juan Pedro Espinós Manzorro, Jorge Gil, Francisco Yubero Valencia
The general objective of the 'CERAMGLASS' project is to reduce the environment impact of thermal treatment of ceramics by the successful application of an innovative laser-furnace technology on planar ceramics and glass. The project plans to construct a pilot plant based on the innovative combination of a continuous furnace and a scanning laser. It aims at demonstrating a considerable reduction in energy consumption and the industrial scalability of the process.
The project primarily aims at showing that it is feasible to produce robust ceramic tile of only 4 mm thick. This would represent a 50% reduction in tile thickness, with consequent reduction in consumption of raw source materials. The project will adapt decoration compositions with more environmentally friendly materials by using the laser processing. Specifically it will adapt screen printing decorations to third-fire products with lustre and metallic effects and decoration inks for planar glass. The replacement of toxic starting materials will allow a minimisation of CO2 and other gas emissions, toxic residues and a reduction of the energy consumption of the process.
Functional porous thin films and 1D supported oxide nanostructures for the development of thin film microfluidics, photonic, valves, and microplasmas (POROUSFILMS)
01-01-2011 / 31-12-2013
Research Head: Francisco Yubero Valencia
Financial Source: Ministerio de Ciencia e Innovación
Code: MAT2010-18447
Research Team: Agustín R. González-Elipe, Juan Pedro Espinós Manzorro, Alberto Palmero Acebedo, Rafael Alvarez Molina, Juan Carlos González González, Victor J. Rico Gavira, Jorge Gil Rostra, Ana Isabel Borrás Martos, Lola González García, José Cotrino Bautista
Functional TiO2, ZnO, SiO2 and doped SnO2 in the form of porous thin films and other supported fiber-like nanostructures will be prepared by plasma deposition and evaporation at glancing angles (GLAD). Precise control of the nano and microstructure of the films and fibers will be attained by selecting appropriate GLAD deposition conditions and, in the case of plasma deposition, by adjusting the principal plasma parameters after modelling the plasma processes and sheath-related phenomena that control the development of the film/fibers nanostructure. The primary objective of the project is to successfully tailor the porosity and other key properties (optical, electrical conductivity, wetting behaviour etc.) of the synthetized materials to enable novel methods of fluid handling (liquids and gases) at the micro and, possibly, nanoscales so as to invent and develop applications in the fields of microfluidic and microplasmas. A further objective is the processing of these structures in both 2D (i.e., lithographic processsing) and 3D by use of laser-based techniques, multilayer stacking of different porous thin film structures and/or selected plasma deposition of hydrophobic patches of other materials such as polymers, silicones, etc. Microfluidic thin film-based devices controlled by light (i.e., photonic valves) will then be developed by employing appropriately designed TiO2 and ZnO porous structures. These materials become superhydrophilic when illuminated with light of <390 nm which will be used to selectively illuminate very small areas (channels, micrometer circuits, etc.) by either a suitable lamp or a laser. Light-controlled microfiltration is envisaged as another new application in this field, whereby preferential diffusion/filtration of polar liquids through the illuminated zones may be induced (i.e. valve open). Achieving prompt reversal of this process (i.e. valve closed) is another challenge that will be addressed by the project. A final, exploratory objective is the modelling, design and development of microplas-mas based on the most promising thin film porous structures developed during the earlier phases of the work. These prototype microplasma devices will consist of porous doped SnO2 thin film electrodes permeable to gases with porous insulator layers (SiO2) acting as separation barriers. Evaluation of the plasma characteristics of these prototype devices will be another distinct task undertaken by the project.
Gold based nanostructured catalysts for selective oxidation reactions
1-01-2011 / 31-12-2011
Research Head: Juan Pedro Holgado Vázquez
Financial Source: Ministerio de Ciencia y Tecnología
Code: CTQ2010-21348-C02-01
Research Team: Alfonso Caballero Martínez, Víctor Manuel González de la Cruz, Fátima Ternero Fernández, Richard M. Lambert
The aim of the proposed project is the development of highly active gold-based catalysts for selective oxidation processes. In these context, benzyl alcohol oxidation (and derivatives) under mild conditions and low temperature CO oxidation in connection with applications in Environment Catalysis as the air control (CO-removal from air) and applications in Catalysis for Energy as the purification of H2 produced by reforming (CO removal from H2) will be considered.
The outstanding properties of gold, a biocompatible non-toxic metal, can be exploited in catalysis when used in highly dispersed form. In order to get elevated yields and selectivities, doubly nanostructured (considering both the active phase and support) gold-based catalysts deposited onto CeO2 and TiO2 (Al2O3 and SiO2 as references) will be prepared. Monometallic gold catalysts will be prepared with control of size and shape of the Au particles, taking advantage of the observed “structure sensitivity” of the proposed reactions. In the same context, it has been recently reported that bimetallic composition based on Gold (AuPd, AuCu, etc) may enhance the performance of these catalysts. Therefore bimetallic catalysts such as AuPt, AuCu and AuNi, will be explored and tested.
Immobilization of cations in high-density charge confined spaces: management of harmful cations wastes
01-01-2011 / 31-12-2013
Research Head: María Dolores Alba Carranza
Financial Source: Ministerio de Ciencia e Innovación
Code: CTQ2010-14874/BQU
Research Team: Miguel Angel Castro Arroyo, Maria del Mar Orta Cuevas, Mery Carolina Pazos Zarama, Said ElMrabet, Esperanza Pavón González, Maria Villa Alfageme, Santiago Medina Carrasco, Ana Isabel Becerro Nieto, Alberto José Fernández Carrión
The central subject of this Project deals with the environmental technological exigency for development of advanced technologies for the elimination of polluting agents. The interest and the effort dedicated to the development of new technologies that allow more effective treatments of retention and new procedures of valorisation is increasing in numerous R&D plans in the last years. It is in this scene where the present proposal must be fitted and circumscribed into two experimental basic findings: designing expansible high layer charge silicates with a controlled distribution of active centres, which can be effective materials for the retention of hazardous and radioactive wastes, and obtaining insoluble disilicate phases in smooth conditions, appropriate for the immobilization of such species. This objective represents a qualitative change in the work that has been developed up to now in relation to the elimination of radioactive and toxic wastes as well as in the application of the methodology to silicate systems. The objectives are adapted, in general, to the high-priority lines of Basic Investigation of Chemistry, in the area of Inorganic Chemistry (Solid State Chemistry) and Environmental Chemistry in particular but, in spite of its basic character, the Project is adapted to diverse lines of investigation of Oriented Chemistry and it is supported by different EPOs (ENRESA, BEFESA and ALQUIMIA). These objectives, of eminent basic character, require the development of techniques of sophisticated analysis like advanced Solid State NMR, X-ray diffraction, under conditions of controlled pressure and temperature or gamma spectroscopy of low counts. This fact fits to the particular objective of the Chemistry Area of “using the instrumental and experimental technology for the study of materials” and with objective O2.5 (Enhance the availability of interdisciplinary infrastructures and sharing use of them) of the R+D+I National Plan 2008-2011. A guarantee of this proposal is that, in a first place, the Research Group (RG) has recently published the synthesis of expansible mica using a method that allows obtaining the desired layer charge in the material; secondly, the RG has a wide experience in the design of synthesis mechanisms of silicates as demonstrated by the number of papers published on this area during the last decade, and, finally, the RG has developed useful methodologies for the present Project in collaboration with other Groups with which it maintains a narrow scientific relationship.
Mechanosynthesis of technological materials
01-01-2011 / 31-12-2011
Research Head: Francisco José Gotor Martínez
Financial Source: Ministerio de Ciencia e Innovación
Code: MAT2010-17046
Research Team: M. Jesús Sayagués de Vega, Concepción Real Pérez, M. Dolores Alcalá González, José Manuel Córdoba Gallego, Ernesto Chicardi Augusto
High-energy ball milling devices, such as planetary, vibratory and attritor mills, intro-duce into the starting powders increasing amounts of energy. Collisions and friction between the balls and between the balls and the wall of the vial result not only in a steadily reduction of particle size, but also induce solid state chemical reactions. During high-energy milling, inti-mate mixing of reactants takes place and fresh surfaces are continually created, which make possible that solid-state reactions progress gradually at room temperature. The new phase has frequently a nanometric character and a great amount of defects, which favours a subsequent sintering process. The mechanochemistry method represents an attractive and alternative route in the synthesis of nanocrystalline materials. Mechanochemical techniques are simple, flexible, and able to prepare a large variety of materials in a bulk-manner at room temperature. Mechanochemistry has been revealed as a practical way to obtain cost-effective materials and more convenient than other synthesis methods because of avoiding the use of heat and solvents can reduce environmental contamination. Due to an almost infinite compositional flexibility, mechanochemistry is suitable for the production of complex solid solutions and composites because of excellent powder homogeneity can be achieved at the same time as the nanostructure. In this project, the ability of mechanochemistry to produce easily and in a re-producible manner different materials that sometimes cannot be synthesized via conventional routes is explored. The following systems have been selected: (i) carbides, nitrides, and borides of transition metals, and (ii) oxides with a perovskite structure and general formula (A1-xA’x)(B1-yB’y)O3-z (A/A’=La, Sr; B/B’=Mn, Cr, Mg, Ga). In the first case, the aim is to develop composite materials based on complex solid solutions of the after-mentioned refractory compounds for structural applications. In the second case, the final goal is to design solid oxide fuel cells where all the components possess the same perovskite structure and similar chemical composition. In addition, the study and modelling of high-energy ball milling processes will be intended in order to permit more easily the scaling-up of the process.
Plasma CVD synthesis of novel organic nanostructured materials integrated in planar devices for photonic sensing and security applications NANOPLASMA
01-01-2011 / 31-12-2013
Research Head: Angel Barranco Quero
Financial Source: Ministerio de Ciencia e Innovación. Programa FEDER Unión Europea
Code: MAT2010-21228
Research Team: Ana Borrás Martos, Agustín R. González-Elipe, Carmen Ruiz, M. Carmen López-Santos
NANOPLASMA proposes the development of novel techniques based on plasma for the synthesis and processing of new organic functional materials. In contrast with the established plasma technology used in plasma enhanced CVD and plasma polymerization that implies the complete fragmentation of volatile precursor molecules, NANOPLASMA processes achieve the synthesis of new families of fluorescent thin films and supported 1D nanomaterials by controlling the chemistry and fragmentation degree at the boundaries of plasma discharge. The research focuses in the synthesis of organic matrices with a well controlled nanometric microstructure incorporating luminescent dye molecules (i.e. perylenes, rhodamines, phtalocyanines y porphirins) and 1D luminescent organic nanowires formed by similar molecules. The project also contemplates the development of methodologies based on the plas-ma etching and laser ablation for the production of 2D lithographic patterns of the lumines-cent thin films and nanostructures. The research in this line will be completed with basic stud-ies aiming the development of a “chemical patterning” process based on the plasma surface functionalization and chemical derivatization of self-assembled monolayers. Both the synthetic methodologies and the patterning strategies of NANOPLASMA are fully compatible with the present optoelectronic and silicon technologies and can be adapted to wafer scale integration for mass scale production. These materials and processes will be used for the fabrication of two types of proto-type devices: photonic gas sensors and luminescent microstructures for intelligent labelling applications. The gas sensing devices consist of a luminescence film and/or structure integrat-ed onto a 1D photonic crystal with a stacking defect designed and constructed to couple the luminescent signal of the sensor layer. The intelligent labelling devices are patterned litho-graphic structures made on single or multilayer structures of luminescence films with specific functionalities and environmental responses not achieved by any available technology.
Systems for the detection of explosives in publlic infrastructures
1-09-2010 / 31-10-2011
Research Head: Angel Barranco Quero
Financial Source: Ministerio de Industria (Contrato: ARQUIMEA)
Code: Centro para el Desarrollo Tecnológico Industrial (Programa CENIT)
Research Team: Francisco Javier Aparicio, Agustín R. González-Elipe, Ana Isabel Borrás Martos, Juan Pedro Espinós
The objective of the project is the development of thin films with adequate optical properties for their use as active elements in optical gas sensors capable of responding to the presence of gases and/or volatile products produced by the partial decomposition of explosives.
Development of bones regeneration membranes modified at nanometric scale (OSTEOMEM)
03-02-2010 / 02-02-2013
Research Head: Agustín R. González-Elipe
Financial Source: Junta de Andalucía
Code: P09-CTS-5189 (Proyecto de Excelencia)
Research Team: José Cotrino Bautista, Rafael Alvarez Molina, Carmen López Santos, Jorge Gil Rostra, Antonia Terriza Fernández
OSTEOMEM aims at developing disposable and biodegradable membranes for bone regeneration to be use in chirurgic oral and maxillofacial implants for the treatment of defects. During the healing of the bone defects, membranes must simultaneously preserve the formation of soft tissues and promote the filling of the hole by the new bone, so that, after the reabsorption of the membrane, the structure of tissues would be similar to that prior to the chirurgical intervention. To achieve that, the membranes should degrade within the body in a period of four-six months, thus avoiding the need of a second intervention required to remove non-biodegradable membranes. It is expected that the membranes developed in the project are comparable to that of animal membranes and avoid the problems associated with the use of these latter.
Flexible hybrid nanostructures for applications as ultraviolet, visible and near infrared filters
03-02-2010 / 03-02-2013
Research Head: Hernán Míguez García
Financial Source: Junta de Andalucía
Code: FQM6090
Research Team: Mauricio Calvo Roggiani, Agustín Mihi Cervelló, Silvia Colodrero Pérez, Nuria Hidalgo Serrano, Gabriel Lozano Barbero, Olalla Sánchez Sobrado
This project aims at developing radiation filters and screens in the shape of films and capable of blocking or selecting ultraviolet (UV), visible (Vis) or near infrared (NIR) radiation within well-defined spectral ranges. Biocompatibility, flexibility and specific adhesive proper-ties will be sought after in order to make these films usable to protect all types of ill, wounded or burnt skin. The aim is to fill a currently existing hole in the field of skin phototherapy based on the healing properties of UV-Vis-NIR light, which is the absence of biocompatible patches in which selected ranges of the electromagnetic spectrum wavelengths can be sharply blocked or allowed to pass depending on the needs of the patient. For clinical cases that so required, an integral approach to skin photo-healing will be taken, devising materials that allow therapeutic wavelengths to reach the skin while blocking harmful ones and providing the controlled topical release of substances that have a beneficial effect on the skin. This project is based on a new series of novel prototype materials that have recently been developed in the group headed by the applicant in the Institute of Materials Science of Seville.
Functionalized for hypethermia applications and evaluation of ecotoxicity
03-02-2010 / 02-02-2013
Research Head: Asunción Fernández Camacho
Financial Source: Junta de Andalucía
Code: P09-FQM-4554
Research Team: J. Blasco, M. Hampel, Carlos López, L.M. Lubián, I. Moreno, Miguel Angel Muñoz, David Philippon, T. Cristina Rojas, Inmaculada Rosa, Carlos García-Negrete
This Excellence project is taking profit of the previous experience of the group TEP-217 in the development and characterization of functionalized biocompatible nanoparticles and potentially trying to advance in four directions. a) Continue with the development of nanoparticle based mainly on Au, Ag and magnetic oxides with different functionalizations and microstructure. b) To deepen the physical-chemical interaction with electromagnetic fields (in a wide range of frequencies from kHz to GHz) to produce local heating. Currently, various mechanisms have been proposed (Eddy current, hysteresis, relaxation of magnetic moments and Brownian motion) without enough data yet existing to understand and interpret the experimental results. c) Establish a multidisciplinary collaboration with the group RNM-306, a specialist in ecotoxicity testing, to improve the knowledge of the environmental impact of nanoparticles (mainly gold and silver) in marine ecosystems, which are the ultimate sink for a good part of nanomaterials currently produced. d) Conduct preliminary studies of the toxicity of nanoparticles as a function of applied magnetic field. In any project dedicated to nanotechnology is extremely valuable to introduce studies to determine the toxicological and environmental impact of new materials being developed at present. A key objective of this project is the training of research personnel through the implementation of one doctoral thesis at the Institute of Materials Science of Seville.
Integration of microchannel catalytic reactors for hydrogen production from alcohols
1-01-2010 / 31-12-2012
Research Head: José Antonio Odriozola Gordón
Financial Source: Ministerio de Ciencia y Tecnología
Code: ENE2009-14522-C05-01
Research Team: Miguel Angel Centeno, Svetlana Ivanova, Francisca Romero Sarria, M.Isabel Domínguez, Sandra Palma, Oscar Laguna, Ana Penkova, Sylvia Cruz, W.Yesid Hernández, Luis Bobadilla
The widespread use of portable electric and electronic devices increases the need for efficient autonomous power supplies (up to 50 We) that replace the currently predominant battery technology. The use of common fuels/chemicals, such as hydrocarbons or alcohols, as an energy source is a promising alternative when combined with the recent developments in microchannel reactor technology. In the previous project (MAT2006-12386-C05) we began to explore the use of micro-channel reactor technology to generate hydrogen on site and on demand by processing alco-hols which has allowed the manufacturing of microreactors for the catalytic steam reforming of methanol and CO preferential oxidation (PROX) reactions. In the present project, the main focus is set on the scaling up of the already designed microreactors which will allow the fueling of a 50 We commercial fuel cell (PEMFC) and the integration of both, the material and thermal flows generated in the fuel processor and the fuel cell, including the production and cleaning steps required by the PEMFC. In addition to this, the development of microreactors for the catalytic steam reforming of ethanol and the water-gas-shift (WGS) reactions is considered in this project for increasing the versatility of the designed device. The feasibility of this kind of autonomous power supplies would require the study of the manufacturing, scaling up of the microreactors and material and thermal flows integration, but also to explore the use of easily available materials (new steels adapted to use), the ageing behaviour of devices (steel, catalysts, sealings, …) and the development of a control algorithm of the fuel processor/fuel cell system.
Bioener: Aplicación de tecnologías biomiméticas a sistemas energéticos
01-01-2010 / 31-12-2012
Research Head: Julián Martínez Fernández
Financial Source: Junta de Andalucía
Code: P09-TEP-5152 (Proyecto de Excelencia)
Research Team: Manuel Jiménez Melendo, Antonio De Arellano-López, Alfonso Bravo León, F.M. Varela Feria
Technological advances have made possible to diversify and optimize energy produc-tion, which in turn has motivated the development of new ways to store energy. In particular, as production methods diversify, it is necessary to develop new materials for energy storage, both large scale and in consumer devices and transportation. This is especially important in the context of higher penetration of renewable energies, which often depend on climatological conditions and require ways to store excess energy at production peaks, so it can be used when production decreases. In parallel to this strategy and to reduce the share of fossil fuels in the overall energy production, it is necessary to increase the efficiency of conventional power generation sys-tems, for example by increasing material’s life and operating temperatures, for example in gas turbine systems, among others. The development of materials for high temperature applications, especially ceramics, has been traditionally linked to the search for increased efficiency of power generation systems. Ceramic materials, due to their high melting point, good creep resistance and resistance to corrosion, are seen as candidates for application in chemically aggressive environments at temperatures over 1000 ºC. Carbides and nitrides in particular are being studied extensively for this kind of applications. Porous ceramics are also of great interest in energy applications, such as heat exchangers or syngas filtration systems, among others. Among active research lines in the development of new materials for energy storage, electrochemical storage is expected to have the largest impact in the end consumer, as the design of high capacity batteries and electrochemical capacitors is key for the viability of tech-nologies such as plug-in electric cars. For this reason, research into new materials for electro-chemical storage has become a strong focal point among the scientific community and consti-tutes one to the great technological challenges of today. Biomorphic silicon carbide (bioSiC) is a ceramic material obtained by reactive infiltra-tion of carbon performs derived by pyrolysis of natural precursors. The precursor, usually wood, is rough-machined and then converted to carbon by pyrolysis in a controlled atmos-phere at high temperatures. The result is a macroporous carbon material (bioC) with a micro-structure that closely resembles that of the original precursor. This carbon template is then machined to near net shape and is melt reacted with silicon either in liquid or vapor phase to obtain a SiC composite with some residual Si that shows excellent thermomechanical proper-ties and a microstructure that closely mimics that of the original wood precursor. Tailoring the material’s properties is possible by adequate selection of the precursor, which determines the microstructure and thus the properties of the bioSiC. It is also possible to remove the remaining silicon through chemical etching to obtain a macroporous SiC material which can then be reinfiltrated to create novel composites and cermets, such as bioSiC/Al or bioSiC/Cu. The prospect of producing macroporous carbon materials with controlled nanoporosi-ty is interesting for electrochemical applications, as it would be possible to infiltrate or coat macropores with a second phase the provides additional function, for instance in three dimensional lithium batteries [3, 20] or carbon/oxide supercapacitors [4, 5]. In this way, the development of new carbon materials with controlled structure and porosity could open the door to novel architectures and designs for devices able to store larger amounts of energy. Most nanoporous carbon materials used nowadays are obtained through activation of carbons made from pyrolysis of synthetic precursors [21], although in the last years carbide-derived carbons have been the subject of great interest [22, 23, 24]. It is possible to obtain high-purity nanoporous carbon through high temperature chlorination of metallic carbides, which rank among the best carbon materials for electrochemical applications. In this direction, is has already been shown that carbides obtained from natural precursors, such as bioSiC are viable precursors to carbide-derived carbons [25]. This proposal’s aim is two-fold: on one side, the bioC processing will be studied in de-tail, paying special attention to precursor selection and to the possibility of introducing differ-ent atmospheres during the pyrolysis process, such as CO2 or water vapor, that promote nanoporosity in the material. The effect of processing parameter in the degree of crystallinity, nanoporosity, crystallite size and structure of the resulting carbon material will be assessed. The possibility of promoting carbon graphitization through the use of different catalysis in the pyrolysis process will be studied. The resulting carbon’s microstructure and physical properties will be studied and correlated to the processing parameters. On the other side, the effect of the aforementioned treatments on the bioSiC material will be studied, and the possibility of obtaining novel cermets in-situ, such as bioSiC/Al, bioSiC/Ti, through melt infiltration, will be assessed. In a last step, the possibility of obtained carbon materials with enhanced structure from the ceramic carbides will be explored.
Catalytic reforming of glycerol
01-01-2010 / 31-12-2012
Research Head: José Antonio Odriozola Gordón
Financial Source: Junta de Andalucía
Code: P09-TEP-5454 (Proyecto de Excelencia)
Research Team: Luis F. Bobadilla Baladrón, Sylvia A. Cruz Torres, M. Isabel Domínguez Leal, Anna Dimitrova Penkova, Francisca Romero Sarria, Andrea Alvarez Moreno
The main objective of this Project is the production of Hydrogen from glicerol steam reforming. Glycerol is the most important by-product of the biodiesel production from the transterification of fatty acids. In the year 2010, the estimated production of biofuels was about 9.9 millions of tonnes, which represents 50% of the aims of the European Union objec-tives. The current energy system needs the development of alternative energetic models. The use of hydrogen as energetic vector is one of these alternatives, but, to assure the sustainability, its production must be from renewable sources. Among the possible renewable sources of hydrogen, the main advantage of the use of glycerol is the almost neutral carbon balance. In addition, the glycerol valorisation must lead to increase the profitability of the bio-refineries that, differently, would meet affected by the increase of costs associated with the elimination of this product.
Mesoporous materials (HA-SBA-15) functionalized with a collagen-targeted rhBMP-2 and their related collagen hybrid composites for bone tissue engineering
01-01-2010 / 31-12- 2012
Research Head: M. Aránzazu Díaz Cuenca
Financial Source: Ministerio de Ciencia e Innovación
Code: BIO2009-13903-C02-02
Research Team: M. Lourdes Ramiro Gutiérrez
A key component in tissue engineered materials for bone repair and regeneration is the scaffold that serves as a template for cell interactions and the formation on bone-extracellular matrix. This scaffold material also provides structural support to the newly formed tissue. Materials in the ternary system SiO2-CaO-P2O5 have demostrated excellent bioactivity for their use in orthopaedic repair and regeneration. The development of new synthesis routes which combine sol-gel chemistry and Block Copolymer (BCPs) self-assembly procedures have potential to be used as interesting methods to produce mesoporous organised SiO2-CaO-P2O5 materials with improved surface area and reactivity. Previous work carried out by the PI of this application has resulted in the synthesis of a biocompatible material (HA-SBA-15) consisting of calcium phosphate hydroxyapatite (HA) nanoparticles growth within a mesoporous (nano-sized-pore-organised) silica SBA-15 structure. Among their biocompatibility, the high surface area and the ordered distribution of pores with very homogeneous size confers to this material very interesting properties for their application as a matrix material for the adsorption of therapeutic agents, drugs or growth factors with requires their application in a controlled and prolonged release. The bone morphogenetic proteins (BMPs) have been widely used because their potent osteinductive properties and certain recombinant proteins BMP-2 and BMP-7 have been approved by the FDA for their use in orthopaedic surgery. Nevertheless, the use of these growth factors is not very extended due to the very high costs of these treatments and the fear to possible undesired side effects due to the use of high concentrations without any controlled delivery system. On the other hand, recent achievements of the team coordinator of this project application (Subproject 2) has produced and patented a recombinant BMP (rhBMP-2) with an additional decapeptidic collagen type I binding domain (CBD) which has shown that this fusion protein has advantages over native BMP-2, and that its combination with collagen may be better and safer alternative for bone repair. In this SubProject application we propose to work in new synthesis routes to produce a nanostructured composite material (HA-SBA-15) with variations in the textural and HA nanoparticle parameters to optimise improved collagen targeted BMP-2 protein adsorption capacities and delivery properties capacities and kinetics. A related objective will be to find and asses the experimental conditions and variables to incorporate successfully a collagen targeted BMP-2 protein to the nano-organised material. The study will cover the analysis of the biomolecule loading, desorption kinetics and final integrity. A second task of the proposed project will be the consolidation of the nano organised powder precursors in 3D ceramic-collagen hybrids composite scaffolds structures which fulfil requirements of biocompatibility, macroporosity and minimal mechanical stability for be using in the in the vivo experimental models which will be carried out as part of the working plan of the other SubProject (Subproyect 2). Work will be carried out to develop fabrication methods of the nanostructured materials into 3D scaffolds while retaining their nanostructural features. The integration of both the protein free HA-SBA-15 and also the fuctionalised collagen targeted BMP-2 material will be considered.
Microestructura y deformación plástica a alta temperatura de óxidos eutécticos basados en Al2O3. Superplasticidad
01-01-2010 / 31-12-2012
Research Head: Manuel Jiménez Melendo
Financial Source: Ministerio de Ciencia y Tecnología
Code: MAT2009-13979-C03-01
Research Team: Julián Martínez Fernández, Antonio Ramírez De Arellano-López, Alfonso Bravo León, Caroline Clauss Klamp, F.M. Varela Feria, C. Vaquero Aguilar
This research addresses to produce binary and ternary oxide eutectics –specifically, Al2O3/ZrO2, Al2O3/Y3Al5O12(YAG), Al2O3/ZrO2/YAG and Al2O3/SiO2/ZrO2, zirconia being stabilized with different amounts of Y2O3– with well-controlled microstructures in the micro- to nanometric range for structural and thermal applications in efficient-enhanced power generation and conversion systems: fuel cells, chemical and high-temperature gas cooled reactors, thermal barriers of steels and super alloys in gas turbines and diesel engine components, etc. These materials are very attractive because of their excellent properties: high melting point, low density, thermal conductivity and chemical reactivity, and superior mechanical performance at both low and high temperature: mechanical strength close to 5 GPa at room temperature, and high creep, wear and erosion resistance. Very recently, superplasticity has been discovered in nanosized materials by the applicant team. Oxide eutectics will be produced by laser-assisted processing techniques in three configurations: bulk, plates (on ceramic and metallic substrates) and multilaminates. For the later configuration, microarquitectures with optimized residual stresses will be designed for enhanced mechanical and thermal performance. The residual stresses will be investigated by using piezo- and Raman spectroscopy, and the data compared to numerical predictions. Laser techniques will be also used to modify the microstructure of conventional ceramic coatings deposited on metallic engine components by Air Plasma Spray, and for machining of ceramic components to obtain a given functional geometry or to modify the external surfaces for improved wear behavior. One of the main goals of this Project is to produce materials with nanosized phases in order to achieve superplasticity (which contrasts with the superior creep resistance of mi-crosized materials). This capability opens the possibility of using superplastic joining and forming as processing methods for complex pieces with near net shape, recovering back its characteristic resistance after thermal treatments. The mechanical properties (flexural and compression resistance, elastic modulus, hardness, toughness and wear) will be evaluated from room temperature up to 1950 K in air as well as under other different environmental atmospheres in order to investigate their effect in the mechanical behavior or material degradation. A significant part of the Project is the structural and microstructural characterization of the as-received materials, and their evolution during mechanical tests. Such an investigation is critical to establish relationships between the experimental mechanical behavior (necessary for engineering designs) and the microstructural and processing parameters. To this end, techniques of optical (particularly confocal), electron (image, microanalysis and diffraction) and atomic force microscopy, and X-ray diffraction with texture facilities will be used. Mechanical and microstructural data will feedback the fabrication process in order to obtain materials with tailored properties for specific applications.
Polymeric and hybrid nanocomposite thin films for photonic and photovoltaic applications (NANOPHOTON)
01-01-2010 / 02-02-2013
Research Head: Angel Barranco Quero
Financial Source: Junta de Andalucía
Code: P09-TEP-5283 (Proyecto de Excelencia)
Research Team: Ana Borrás, Fabián Frutos, Lola González-García, Said Hamad, S. Lago, Alberto Palmero, Carmen Ruiz-Herrero, Juan R. Sánchez-Valencia, Johan Toudert
The Nanophoton project aims the development of a novel family of materials, struc-tures and device prototypes for application in solar energy, environmental sensing and space communication technology. The starting point of the project is the research in the photonic properties of hybrid nanometric films. These functional thin films will be processed and inte-grated in optical structures. The project encompasses fundamental molecular simulation studies, the development of novel nanometric functional structures, the study of suitable processing/integration procedures and the validation of prototype devices. These devices will be of three kinds: photonic gas sensors, detectors insensitive to the angle of detection for diffuse optical communications and photovoltaic cells. An interesting characteristic of the Nanophoton technology will be its fully compatibility with the current optoelectronic and microelectronic industrial manufacturing processes.
Role of additives in the reactive hydride composite systems for hydrogen storage
01/01/2010 - 31/12/2012
Research Head: Asunción Fernández Camacho
Financial Source: Ministerio de Educación y Ciencia
Code: CTQ2009-13440
Research Team: Carlos López, Cristina Rojas Ruiz, Gisela Arzac, Dirk Hufschmidt, Raimondo Ceccini, Emilie Deprez
Due to the expected short-medium term exhaustion of fossil fuels and due to clime changes produced by the green house effect, it is necessary to reconsider a new global energy policy. Hydrogen, as a vector for energy storage and transport, is an attractive candidate for a clean handling of energy. In the present project it is proposed the study of the so called reactive hydride composite systems (RHC) for hydrogen storage. These systems are based in the coupling of a single metal hydride (i.e. MgH2) with a complex hydride (typically a borohydride compound, i.e LiBH4) to give a reversible reaction that is producing or consuming hydrogen. The system can so be used as a hydrogen storage material according to following reaction: MgH2+2LiBH4 ↔ MgB2+LiH+4H2 (11.4 wt% hydrogen storage capacity). The reaction is improving the heat transfer handling, as compared to pure MgH2, by reducing heat release during the charging process. To improve the kinetic aspects (reduction of operation temperatures and times) it has been proposed the use of catalysts a/o additives. The main objective of the project is to understand the role of these additives to improve the hydrogen sorption kinetics. In particular commercial Ti-Isopropoxide (TiO4C12H28) , TiO2 and VCl3 have been selected as additives for this study. Also other catalysts like Co3B, Ni3B or RuCo will be prepared in our laboratory and also tested. The systems will be prepared and activated by high energy ball milling of the two hy-dride materials milled together with or without the additives (5-10 mol%). Kinetic studies will be carried out by gravimetric and volumetric hydrogen sorption measurements (hydrogen desorption or adsorption vs. time at constant T) and differential scanning calorymetry (DSC) analysis. An exhaustive microstructural and chemical analysis of the systems at the different step (as prepared, desorbed and re-absorbed) will be undertaken by following techniques: X-Ray Diffraction (XRD), Transmission Electron Microscopy (TEM) coupled to EDX (energy dispersive X-Ray) and EELS (Electron Energy Loss Spectroscopy) analysis, X-Ray Photoelectrton Spectroscopy (XPS) and X-Ray absorption Spectroscopy (XAS). The comparative study of the samples, with and without additives, and the correlation between the kinetic studies and the microstructural and chemical analysis, should clarify the mechanisms of the kinetic improvements produced by the additives. These mechanisms are today far from being understood. On basis of the acquired knowledge we expect to significantly improve the systems with respect to hydrogen storage applications.
Study of the degradation processes on the materials used in the manufacture of historical organs
2010 / 2013
Research Head: Angel Justo Erbez
Financial Source: Ministerio de Ciencia e Innovación
Code: MAT2010-20660
Research Team: Adolfo Iñigo Iñigo, Juan Poyato Ferrera, José Luis Pérez Rodríguez, Liz Karen Herrera Quintero, Angel Justo Estebaranz, Adrián Durán Benito, M. Carmen Jiménez de Haro, Belinda Sigüenza Carballo
The main objective of the project is to know the composition, microstructure and mechanical properties of tin-lead alloys from Spanish historical pipe organs. Also, we will study the degradation and corrosion processes on the pipe organs and the products of corrosion produced by these processes. Analyses will be performed in Spanish research and technological institutes (ICMSE, AIMEN, IRNASA) and European facilities (ESRF, C2RMF). This objective pursues to know the vectors that produce the corrosion, like the volatile compounds from the wood and other organic materials used in the construction of pipe organs, water vapour and/or carbon dioxide. The work will be carried out in materials with different grades of corrosion taken in the organs, including alloys and woods. Also, alloys with different tin-lead ratios, and with traces of other elements (As, Bi) will be prepared and will be undergone to corrosion tests. Results from the composition and results of tensile and creep tests will be correlated with the corrosion rate. The results obtained in the laboratory will be compared with the samples coming from the organs, and conclusions will be reached about the possible alteration causes, the suitable compositions for the restorations, and the most resistant alloys to the corrosion, to apply them to the construction of new organs.
The coupling of grain boundary dynamics and impurity segregation in nanostructured polycrystals: application to yttria tetragonal zirconia polycrystal (YTZP)
01/01/2010 – 31/12/2012
Research Head: Diego Gómez García
Financial Source: Ministerio de Educación y Ciencia
Code: MAT2009-14351-C02-01
Research Team: Francisco Luis Cumbrera Hernández (USE), Arturo Domínguez Rodríguez (USE), Robert Luis González Romero (becario AECID)
This project aims to study, by computer simulation at different length scales, the mi-crostructural evolution of a polycrystal at elevated temperature and under an applied mechanical stress field, with an emphasis on nanometric systems. For this study it is essential to know the law of mobility of the grain boundaries as a function of the temperature and the local stresses. When impurities are present, this law depends critically upon the concentration of segregated chemical species at these boundaries and upon their evolution during the dynamic regime (i.e., during deformation). As segregation itself is altered by the movement of the grain boundary, the two phenomena are coupled. The study of segregation will be carried out by Molecular Dynamics (MD) simulations; MD will also be used to characterize the mobility of a single grain boundary containing impurities. These data will be used as input in a mesoscopic model, which will allow the study of the dynamics of an ensemble of nanometric grains and, consequently, plasticity in this model polycrystalline system. The final objective of this project is to determine the law of evolution of the centers of mass of the grains in order to get, via a statistical treatment, the constitutive law for plasticity in a nanometric polycrystal. This macroscopic law will then be compared with experimental results in nanometric YTZPa system in which the research team has wide experience in recent years.
Applications of photonic crystals in solar cells: power conversion efficiency enhancement though optical absorption amplification
14-01-2009 / 13-01- 2012
Research Head: Hernán R. Míguez García
Financial Source: Junta de Andalucía
Code: P08-FQM-03579 (Proyecto de Excelencia)
Research Team: Manuel Ocaña Jurado, Mauricio Calvo Roggiani, Nuria Nuñez, Agustín Mihi, Gabriel Lozano, Silvia Colodrero, Nuria Hidalgo, Olalla Sánchez Sobrado
Porous photonic crystals introduced in heterojunction solar cells allow to enhance sig-nificantly their photovoltaic performance by increasing the light harvested by the device. This concept, pioneered by the multifunctional optical materials group, have lead to highly efficient and transparent dye solar cells that preserve their potential application as window modules, one of their main added values. The concepts proposed in this project are not only interesting from a fundamental point of view in photonics and energy conversion, but also of clear relevance for building integrated photovoltaics.
Control of Optical Emission and Absorption Properties of Nanomaterials in Photonic Crystals
01-01-2009 / 31-12-2011
Research Head: Hernán R. Míguez García
Financial Source: Ministerio de Ciencia e Innovación
Code: MAT2008-02166
Research Team: Manuel Ocaña Jurado, Mauricio Calvo Roggiani, Nuria Nuñez, Agustín Mihi, Gabriel Lozano, Silvia Colodrero, Nuria Hidalgo, Olalla Sánchez
In this project the modifications of both optical emission and absorption of nano-materiales of different sort (rare earth doped nanoparticles, semiconductor quantum dots, and films of organic dyes of nanometer dimensions) that occur when they are embedded in a photonic crystal structure. Both fundamental and applied aspects of the subject will be ana-lysed, efforts being focused on materials of current technological interest. From the applied point of view, this project finds its motivation in the possibility that photonic crystal offer of modifying those absorption and emission processes in a controlled manner so that they can be inhibited or amplified depending on the specific goal pursued. Particularly, we seek to put into practice these concepts to generate new designs of more efficient solar cells, capable of harvesting a larger amount of the incident radiation, and in the development of films for sensing devices sensitive to modifcations of different kind, such as presence of targeted molecules, variations of ambient gas pressure, etc... In its more fundamental aspect, our project aims at deepening our knowledge of the interaction between light and matter in systems in which there exists a strong dispersion and anisotropy of the dielectric constant, and in which it is possible to attain very low photon propagation speeds. For this analysis, we will employ photonic crystals with three dimensional order as hosts in which a wide range of organic and inorganic nanomaterials will be integrated in different configurations and whose absorption and emission will be experimentally and theoretically studied.
Development of photocatalytic-materials highly activ in the visible for environmental applications
01-01-2009 / 31-12-2011
Research Head: José Antonio Navío Santos
Financial Source: Ministerio de Ciencia y Tecnología
Code: CTQ2008-05961-C02-01
Research Team: Gerardo Colón Ibáñez, M. Carmen Hidalgo López, Manuel Macías Azaña, Marina Maicu
The main goal of this coordinated project is “the tailoring of a new generation of pow-dered materials having nanometer size based on TiO2, SnO2 and ZnO single, mixed an/or doped showing high photoactivity in the visible region (nanophotocatalysts), eventually immobilized on other selected materials (membranes, glass, ceramic tiles, clays and metal films) in order to be used in a competitive and efficiently way to the treatment of pollutants in water and air by using the solar energy”. The principal hypothesis is the existence of inorganic pigments such as TiO2, SnO2 ZnO having high oxidizing power in the UV region that are capable of degrading toxic species present in our environment. The project intends to develop new heterogeneous TiO2, SnO2 and ZnO nanocatalysts exhibiting good optoelectronic properties in the visible region at the same time that the physicochemical properties are being implemented. Two main research activities will be proposed to cover the development of heterogeneous nanosized TiO2, SnO2 and ZnO powders (nanocatalysts) capable to design and develop the photodegradation of pollutants in water and air, by the use of Solar Light (Environmental Solar Chemistry). The project also will address the immobilization of different semiconductor nanoparticles (single, mixed and/or doped) on selected supports (membranes, glass and metal films) with the intention of developing heterogeneous systems exhibiting high photocatalytic activity for their applicability to the treatment of pollutants that would represent an improvement in the catalyst filtration and at the same time, with the generation of self-cleaning surfaces.
Preparation of multiferroic materials by mechanical alloying and termal methods with smart temperatura control
01-01-2009 / 31-12-2011
Research Head: Luis A. Pérez Maqueda
Financial Source: Ministerio de Ciencia y Tecnología
Code: MAT2008-06619
Research Team: Maria Jesús Diánez Millán, José Manuel Criado Luque
Multiferroic materials are those with two or more ferroic properties. There is a signifi-cant interest in those materials due to the large number of possible applications due to their properties. It has been claim in literature that the lack of reliable preparation methods for stoichiometric defect-free compounds hinders the development of applications of these compounds in devices. In this project, we propose the use of two alternative procedures for the preparation of multiferroic compounds: mechanical alloying and thermal decomposition of precursors under smart temperature conditions. The first procedure implies the use of a high-energy mill designed in cooperation with MC2 firm. The mill is connected to the gas system during operation. Thus, it is possible to control pressures up to 20 atm of any reactive or inert gas. The alternative proposed procedure implies the preparation of several precursors and their decomposition under smart temperature conditions. In the smart temperature control methods, the process itself determines the temperature evolution according to a function of the process evolution with time. These methods differ from the conventional ones in the control procedure, thus, in the conventional ones the function temperature-time is fixed while in the smart temperature control methods the process itself determines the evolution of temperature. In previous publications, we have observed that by using the smart temperature procedure, microestructure of samples could be tailored, while by using conventional heating procedures such control could not be achieved. Prepared samples will be characterized in terms of the oxidation state of the different cations, structure, microstructure and properties.
Structure, packing and tribology of Fatty Self-assembled monolayers of Alkylamines
01-01-2009 / 31-12-2011
Research Head: José Jesús Benítez Jiménez
Financial Source: Ministerio de Ciencia y Tecnología
Code: CTQ2008-00188
Research Team: Miguel Salmerón, Eduardo Garzón Garzón, Pedro J. Sánchez Soto, J. Alejandro Heredia Guerrero
The aim of this research project is to study the contribution of molecular scale events to the tribological properties of self-assembled monolayers of alkyl molecules. The amount of topographic and frictional AFM data available on typical self-assembled systems such as thiols on gold and silanes on mica is very extensive. Here, we propose alkylamines on mica as a new self-assembled system. The reason is that the weaker interaction between the amino end group and mica, if compared with S-gold and silane-mica, leads to a less effective molecular packing. The ability to control the quality of molecular packing by tunning the preparation conditions is a good model to test the contribution of defects to friction. Molecular resolution using contact AFM is not possible on alkylamine self-assembled monolayers, so there is a lack of structural information on this system. The new methodology described in this project proposes the use of Scanning Polarization Force Microscopy (SPFM) to address this issue based on the high polarization signal contrast between mica and self-assembled layers. Furthermore, the high sensitivity of SPFM to the presence of water molecules filling vacancies, can be used to evaluate the quality of the molecular packing by monitoring the screening effect exerted by the self-assembled layer. Consequently, the study of both, the frictional and the SPFM properties of self-assembled monolayers of alquilamines, are complementary to describe the contribution of defects to friction.
Study of Surface modified materials and coatings by ReflEXAFS SURCOXAFS
01-01-2009 / 31-12-2011
Research Head: Adela Muñoz Páez
Financial Source: Ministerio de Ciencia e Innovación
Code: MAT2008-06652
Research Team: Stuart Ansell, Regla Ayala Espinar, Sofía Díaz Moreno, Lola González García, José Manuel Martínez Fernández, Víctor López Flores
X-ray Absorption spectroscopy in reflection mode, ReflEXAFS, is a novel technique yielding the typical information from EXAFS, local structure around de absorbing atom, together with that obtained from reflectometry, such as roughness, layer thickness or density within the near surface region. The technique has also the capability of controlling the thickness of the region probed simply by changing the incidence angle, within a rather interesting range, 20-200 Ǻ. Moreover, in contrast with other surface spectroscopic techniques, such as XPS, it allows the study of buried layers. For all these reasons, it is a useful tool to provide structural information of surface materials, such as those with thin layer structure, coatings and surface modified bulk materials. In previous projects we developed measurement protocols for this technique at using model sample. Herewith we propose to apply the technique to real systems of two types: surface modified steels by nitriding treatments and materials made of mixed thin layers with optic and magnetic properties. Apart form the intrinsic interest of the technique itself and the systems which are going to be prepared and studied, this project is relevant in the framework of the development of XAS-based techniques of potential application in the Spanish beamline at the ESRF, SPLINE, as well as in the new Spanish synchrotron source, ALBA.
Surface functionalisation of materials for high added value applications (FUNCOAT)
15-12-2008 / 15-12-2013
Research Head: Agustín R. González-Elipe
Financial Source: Ministerio de Ciencia e Innovación
Code: CSD2008- 00023 (Consolider)
Research Team: Fernández Camacho, A., Espinós, J.P., Yubero, F., Cotrino, J., Sánchez López, J.C., Barranco, A., Palmero, A., Rojas, C.
FUNCOAT is an integrated project within the application call CONSOLIDER-INGENIO 2010 aiming at the exploitation of synergies existing in the Spanish scientific community, with the general objective of developing principles, processes and devices related to the surface functionalisation of materials. The project integrates 14 well-accredited research centres covering from fundamental and theoretical aspects to final applications. This large effort of integration is critical to achieve substantial advances in this broad field, which go beyond the mere accumulation of results. The research teams belong to different institutions: University, CSIC (responsible for the management of the project) and Technological centres. They maintain scientific relationships among them that extend over the last 15 years. Specific scientific and technological objectives are: understanding of fundamental phenomena driving the modification of surfaces and interfaces, control of the micro- and nano- structure of surfaces and thin films, optimization of thin film deposition methods, process development of multifunctional surfaces for novel applications (mechanical and metallurgical, optical, magnetic, energy, biomaterials, etc) and, finally, the production of new devices based on functionalised surfaces. Other important objectives include the technological transfer of the scientific results to the productive sectors as well as the education and training of scientists, young researchers and engineers. Strategic sectors of our modern society where the activities of FUNCOAT find a direct impact are material processing, energy, environment, health care, agriculture, etc. In order to accomplish an efficient coordination of efforts and the integration of the activities of all the groups, the project is structured around six workpackages: A) Fundamental phenomena in surfaces, interfaces and thin films, B) New processes for the control of the micro- and nano- structure of films and surfaces, C) Mechanical and metallurgical coatings for surface protection, D) Chemical functionalisation and biomedical applications, E) Coatings for optical control, photonic applications and solar energy collection and F) Novel magnetic phenomena in surfaces/interfaces.
Creating and disseminating novel nano-mechanical characterization techniques and standars (NANOINDENT)
01-09-2008 / 31-08-2011
Research Head: Asunción Fernández Camacho
Financial Source: Unión Europea
Code: NMP3-CA-2008-218659
Research Team: Godinho, V., Philippon, D.
Our project aims to gather, improve, catalogue and present characterisation tech-niques, methods and equipment for nanomechanical testing. European-wide activities coordinated by a new virtual centre will improve existing nanoindentation metrology to reveal structure-properties relationship at the nano-scale. These methods are the only tools to characterise nanocomposite, nanolayer and interface mechanical behaviours in the nanometre range. This work will also lay down a solid base for subsequent efforts for defining and preparing new standards to support measurement technology in the field of nanomaterials characterisation. Steps include development of the classical and the dynamic nanoindentation method and its application to new fields, application of modified nano-indenters to new fields as scratching and wear measurement, firm and uniform determination of instrumental parameters and defining new standard samples for the new applications. The virtual centre will disseminate information based on a new “Nanocharacterisation database” built on two definite levels: on a broader level partners will inventory and process all novel nanocharacterisation techniques and, in narrower terms, they will concentrate on nanomechanical characterisation. This will be achieved through the synchronisation of efforts set around a core of round robins but the database will include data of other channels as parallel research work and literature recherché.
Mechanosynthesis of metallic hydrides and multiferroic perowskites in a high energy mil under high pressure
01-02-2008 / 31-03-2011
Research Head: Luis Allan Pérez Maqueda
Financial Source: Junta de Andalucía
Code: TEP-03002
Research Team: Gotor, F.J., Diánez, M.J., Criado, J.M., Alcalá, M.D., Poyato, J., Pérez Rodríguez, J.L., Sánchez Jiménez, P.E.
The main objective of the Project is the use of a high energy mil, developed in cooperation with the firm MC2, ingeniería y sistemas, S.L., that allows controlling the atmosphere during the treatment at pressure of up to 20 bar of any inert or reactive gas, for the preparation of two kinds of materials: modified magnesium hydrides for hydrogen storage and multiferroic ceramics. In this project we propose for the first time the preparation of multiferroic ceramics by mechanical alloying at room temperature. This is a challenging topic because the preparation of such materials requires pressure of up to several GPa. The prepared materials will be characterized in terms of their properties. Metallic hydrides will be prepared by mechanical alloying under high pressure of hydrogen. The prepared materials will be characterized in terms of their structure, microstructure and hydrogen storage behavior, including the kinetics of hydrogenation and dehydrogenation.
Nitrogen Plasmas for the superficial functionalization of materials
01-02-2008 / 31-01- 2011
Research Head: José Cotrino Bautista
Financial Source: Junta de Andalucía
Code: P07-FQM-03298 (Proyecto de Excelencia)
Research Team: Agustín R. González-Elipe, Francisco Yubero Valencia
The project PlasNitro discusses the characterization of nitrogen plasmas in various technological related applications with techniques of deposition and functionalization of materials, reforming and processes of sterilization. Different procedures to measure properties of plasmas will go down to point, plasma that can be used in doping, deposition, functionalization and modification of materials and that contain nitrogen. In all cases by using techniques of diagnosis based in the detection of nitrogen species. Nitrogen is a usual component nowadays, only or in mixtures with other gases, in a lot of processes used in technology of plasma. Its experimental characterization and/or the modeling will allow getting fundamental properties from plasma (electron density, electron temperature, temperature of the gas, reactive species, etc.) and knowing the contribution to the homogenous (in phase plasma) and heterogeneous (in the surface-material interaction) reactions of the appropriate components of nitrogen. Numerical codes to get out the electron energy distribution function in plasma will become elaborate in the project. To this end the evaluation of the vibrational distribution of nitrogen will be necessary previously. This step implies taking into account multiple vibrational-vibrational processes, vibrational-translactional and vibrational-rotational processes. In the project we will be able to obtain models of fluid of the nitrogen plasma with the contributions of the most important species of the plasma. The theoretical calculations will be complemented with experimental measurements using electrostatic Langmuir's probe, this will allow measuring the electron energy distribution function, as well as density and temperature of the electrons. The partial nitrogen pressure in each application and the plasma's neutral components will be controlled by means of an analysis of residual gases. The kinetic modeling of the nitrogen plasma will enable the interpretation of measurements in the plasma out of the thermodynamic equilibrium and by using the Monte Carlo technique of simulation that enable the control of deposition/modification and the nano/microstructure of the materials. We will have, in this way, techniques that they will enable to control themselves and improving the procedures of work and the properties desired in the materials.
Syngas and Hydrogen Production by Hydrocarbon Reforming on Nickel Nanostructured Catalysts (SYNANOCAT)
1-12-2007 / 30-11-2011
Research Head: Alfonso Caballero Martínez
Financial Source: Ministerio de Educación y Ciencia
Code: ENE2007-67926-C02-01
Research Team: Juan Pedro Holgado Vázquez, Agustín R. González-Elipe, Victor Manuel González de la Cruz, Rosa Pereñiguez Rodríguez
The coordinated proposed research project, that seek to be an extension of the references ENE2004- 01660 and ENE2004-06176,pretends to prepare new catalytic systems, with a discrete crystallite size and a higher resistance to deactivation. The aim is to obtain catalysts for an optimum performance in the reforming reaction of hydrocarbons to yield H2(+CO), principally from methane and propane. These reactions being structure-sensitive, are affected by the size of metallic particles.
Nanoparticles of nickel with well controlled size and morphology will be prepared by ex-situ methods as microwave plasma irradiation, ionic liquid, reverse microemulsion or impregnation with external surface modification by silylation. These methods will allow us to obtain metal particles of a very different range of size: from less than 10nm to sizes about 100nm and a narrow particle size distribution. The catalytic activity of these nanoparticles, supported on different oxides as ZrO2 or Al2O3, will be evaluated in the reforming reactions of methane and propane to establish a structure-reactivity relationship. Special attention will be devoted to the carbon deposition over the catalyst in reaction conditions, the more important process hindering the performances of these kind of catalysts. The strict control of the morphology of the particles must allow us to correlate the kinetic of the deactivation process to the different type of nanoparticles. Also, we will evaluate the effect of different kind of additives, as Pt, Au, Sr, K, etc., reported in the literature as beneficial for the overall activity of these materials.
The reforming reactions of hydrocarbon will be alternatively studied in the presence of a microwave generated plasma. We expect finally to develop an integrated thermal-plasma reactor that could permit the reaction at a lower temperature and/or with less deposition of coke over the catalyst.
Ceramic composites and low-dimensional phases to waste management
01-10-2007 / 30-09-2010
Research Head: Miguel Angel Castro Arroyo
Financial Source: Ministerio de Educación y Ciencia
Code: CTQ2007-63297
Research Team: Alba, M.D., Alvero, R., Becerro, A.I., Chain, P., Escudero, A., Naranjo, M., Trillo, J.M.
The main objective of this Project is obtaining composite materials from especially designed expansible and high layer charge laminar silicates containing low dimensional phases with effective activity for the retention and immobilization of toxic and dangerous wastes. The main innovating aspect of the Project arises, on one hand, from the confluence of the studies that the research team has performed with researchers from University of Cambridge (United Kingdom) within the development of the current national project. On the other hand, it arises from the action of reunification of the researchers who participate in a unique multidisciplinary project in the border of the basic chemistry of silicates in connection with the waste management. The proposed hypothesis, elaborated from the results obtained by the research team during the last decade, states that the effectiveness of the elimination of polluting agents by layered aluminosilicates is controlled by the structural disposition and the composition of the low dimensional phases originated during the treatments. Methodology is not limited to synthesis of the composite materials and its characterization, and it incorporates a measurement of the potential which they would represent in the treatment of wastes, essentially based on some organic polluting agents and heavy, toxic and radioactive cations. The development of the Project will affect the relations of the research team with Research Groups of the University of Bayreuth (Germany) and Cambridge (United Kingdom) and the multidisciplinary character of the Project and the noticeable academic and educational character of the team can be considered a guarantee of its high formative capacity.
Multifunctional nanostructured coatings for mechanical and tribological applications (NANOMETRIB)
01-10-2007 / 30-09-2011
Research Head: Juan Carlos Sánchez López
Financial Source: Ministerio de Ciencia e Innovación
Code: MAT2007-66881-C02-01
Research Team: Asunción Fernández Camacho, Cristina Fernández, Miguel Angel Muñoz-Márquez, Said El Mrabet, Vanda Godinho, M. David Abad
In this In the field of mechanical and tribological applications, the investigations are oriented towards the development of new systems capable to increase the performance of industrial operations, machines or tools by increasing the hardness and diminution of the friction and wear rate of materials under contact or increasing the oxidation resistance. These improvements suppose an energy-saving and cost reduction due to increase of tool life-time without needs of reparation as well as a reduction in the employment of lubricant emulsions with oils and greases. This project goal is to develop bew multifunctional nanostructured sys-tems by the Magnetron Sputtering PVD technique for mechanical and tribological applications where an adequate balance among the above-mentioned properties as friction, hardness and thermal stability are searched. The combination of multiple functions into a materials increase noticeably the material added value. To achieve this general objective, different coatings will be prepared by confinement of size and distribution of phases, chemical composition and microstructure in the nanometric regime. The chosen systems are constituted by crystals of hard materials (nitrides, carbides and borides of transition metals: Cr, Ti, W) that can be surrounded by a second phase that acts as lubricant based on C or dichalcogenides of W and doped with certain metals to increase their thermal resistance (V or Nb). In all cases, the project comprises their synthesis, chemical and structural characterization, and their practical validation in tribological tests of friction and wear. The establishment of the relationships between microstructure and measured properties will be an essential objective, since it enables the better understanding of the action mechanisms, and thus, the optimisation of such nanostructured multifunctional systems for an improved technological benefit.
Inmobilization of toxic and radioactive wastes by silicates
28-2-2007 / 1-3- 2010
Research Head: Miguel Angel Castro Arroyo
Financial Source: Junta de Andalucía
Code: P06-FQM-02179
Research Team: Alba, M.D., Alvero, R., Becerro, A.I., Chain, P., Escudero, A., Naranjo, M., Pavón, E., Trillo, J.
In The present Project tries to use high-charged silicates, which are designed under procedures that allow controling the quantity and distribution of the tetrahedral active centers. They will be submitted to a set of chemical soft treatments in order to inmobilize toxic elements. This project will be carried out in collaboration with BEFESA and ENRESA companies. Firstly, the effect that the experimental variables involved in the procedure of synthesis exert on the distribution of the active centers of the materials will be analyzed. In the second stage, the synthetic silicates will be treated under soft hydrothermal conditions with solutions containing carefully selected toxic and radioactive elements. Finally, the degree of retention of these elements in the new obtained phases will be estimated. The Research Team (R.T.) will incorporate an experimental methodology developed by itself that includes the combined employment of Nuclear Magnetic Resonance of Solids, X-ray Diffraction, X-rays Fluorescence and Microfluorescence, which will give information of the long range order and the local environment of the active centers of the residues, responsible of it dangerousness. It will have to give direct and not yet available information of the final mechanism of fixation, which is the main objective of this Project. The expected Results will bring basic useful information about the mechanisms of interaction of metallic ions with the framework of expansible aluminosilicates and its relation with the local arrangement of their atoms. Moreover, it will bring a useful knowledge allowing to develop new suitable procedures for immobilization of industrial waste, in collaboration with the companies of the sector, which marks the innovative character of the Project.
Design of photocatalytic systems highly active in the visible for environmental applications
01-01-2007 / 31-12-2010
Research Head: Gerardo Colón Ibáñez
Financial Source: Junta de Andalucía
Code: FQM-1406
Research Team: José Antonio Navío Santos, Manuel Macías Azaña, Carmen Hidalgo López, Marina Maicu
The heterogeneous photocatalysis has demonstrated to be a promising and efficient technology for the oxidation of a large variety of toxic substrates in relatively short reaction times. It is widely known that the most used photocatalysts can be only activated by means of photons with wavelengths lower than 390 nm, being an important limitation for large scale use. The main objective of this project is based on previous development in our group of highly UV photoactive TiO2 powders able to completely remove different toxic species for the environment. Our challenge is to overcome the problems and limitations of the UV range in the solar spectrum. The core of our activity will be the development of new oxidic photoactive doped systems based on Ti and Zn, which could provide a shift in the absorption edge toward the visible range.
Thus, under the point of view of the enhancement in the photon efficiencies of the photocatalytic processes, it is evident that the designing and development of alternative photocatalysts is of great interest. We intend the obtention of highly efficient materials that can be used for the degradation of contaminants in water and gas effluents by the incorporation of cationic/anionic dopants and the immobilization in different adequate supports.The evaluation of the photocatalytic activity will be performed for the photooxidation of a great variety of toxic organic compounds and using solar simulation lamps.
New Bio-ceramization processes applied to vegetable hierarchical structures
01-10-2006 / 30-09-2010
Research Head: Julián Martínez Fernández
Financial Source: Unión Europea
Code: STRP 033277 TEM-PLANT
Research Team: Ramírez de Arellano-López, A., Jiménez, M., Marrero, M., Clauss, M., Bravo, A., Quispe, J.J.
TEM-PLANT project focuses on the development and application of breakthrough processes to transform plant-derived hierarchical structures into templates for the exploitation of innovative biomedical devices with smart anisotropic performances and advanced biomechanical characteristics, designed for bone and ligament substitution. The TEM-PLANT project primary addresses the nano-biotechnologies area and will push the current boundaries of the state-of-the-art in production of hierarchical structured biomaterials. By combining biology, chemistry, materials science, nanotechnology and production technologies, new and complex plant transformation processes will be investigated to copy smart hierarchical structures existing in nature and to develop breakthrough biomaterials that could open the door to a whole new generation of biomedical applications for which no effective solution exists to date.
Starting from suitably selected vegetal raw material, ceramization processes based on pyrolysis will be applied to produce carbon templates, which will be either infiltrated by silicon to produce inert SiC ceramic structures or exchanged by electrophoresis deposition to produce bioresorbable ceramics. For ligament yielding two processes will be developed: pH-controlled and electrophoresis-controlled fibration to generate fibrous collagenous cords with high tensile strength and wear-resistance.
Crust to core: The fate of subducted material
01-7-2006 / 31-01-2011
Research Head: Ana Isabel Becerro Nieto
Financial Source: Unión Europea
Code: MRTN-CT-2006-035957
Research Team: Universidad de Bayreuth (Alemania), Universidad de Milán (Italia), University College London (Reino Unido), Geological Survey of Norway (Noruega), Universidad Pierre et Marie Curie, París (Francia), Friedrich Schiller Universitat Jena (Alemania), UniverzitaKarlova V Praga (República Checa)
At convergent plate boundaries material is transported from the Earth's surface to its interior; this is one of the central processes in the solid Earth, determining its dynamic, chemical, and thermal evolution. It is linked to a wide range of surface features, ranging from plate tectonics to earthquakes and volcanoes to the chemical evolution of the Earth's atmosphere.Despite this importance many aspects of the subduction process and associated material fluxes are poorly understood to date, and advances in understanding require the integrated efforts of many sub-disciplines in the Earth sciences as well as integration of neighbouring fields. To overcome the fragmentation and advance the basic understanding of the subduction process we form a European network which combines unique facilities and expertise in petrology, experimental and computational mineralogy, analysis, synthesis, and dynamic studies of the Earth's interior.
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