BCMaterials
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| Established | April 25, 2012 |
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| Director | José Manuel Barandiarán |
| Location | Leioa, Basque Country, Spain |
| Website | http://bcmaterials.net |
BCMaterials, which stands for Basque Center for Materials Applications & Nanostructures - BCMaterials Materials Fundazioa, is an autonomous research center located on the Basque Country, Spain. It covers all aspects of research in Functional Materials with advanced Electric, Magnetic and Optical properties; from basic aspects to applications. Special activity is devoted to thin films materials and characterization techniques involving Large International Facilities, like neutron and synchrotron radiation sources.
Aiming a world leadership in Materials Research, the BCMaterials is currently developing his activity in three main lines, namely:
- Active (smart) materials
- Advanced functional materials
- Functional Materials for applications to energy, sensors, accelerators.
All of these lines already count with a number of high level researchers and facilities that are shared with the University of the Basque Country. Specific facilities are a clean room for thin film deposition and nanolithography, Sputtering, Pulsed Laser Deposition and Spin Coating as well as lift-off and RIE facilities for lithography, profilometry, Atomic/Magnetic Force Microscopy, SQUID and Magneto Optical Kerr Effect (MOKE) magnetometry, etc.
Ikerbasque, the Basque Foundation for Science, accorded in March 2011 the creation of a new center of research: the Basque Center for Materials, Applications and Nanostructures. The center will make part of the BERC’s (Basque excellence Research Centers) network.[1][2]
History
On April 2012, the BCMaterials Foundation has been put forward[3] by the contributions of Ikerbasque and the University of the Basque Country. This foundation supports the BCMaterials activities and provides a way for fluid interplay with other academic departments and institutes, technological centers, industry and public institutions.
Aim
The BCMaterials will cover all aspects of research in Functional Materials with advanced Electric, Magnetic and Optical properties; from basic aspects to applications. Special activity will be devoted to thin films materials and characterization techniques involving Large International facilities, like neutron and synchrotron radiation sources.
Location
The final location of the BCMaterials will be the future Science Park of Leioa, within the Campus of the University of the Basque Country (UPV/EHU), where the present activity in Materials, in particular at the Faculty of Science and Technology, constitutes the main resource of Biscay in this field. In a first step, however, the center will be located at the Technology Park of Bizkaia, were activity is already starting.
Active (smart) materials
Active (smart) materials are those that present crossed properties so that they re-act to a stimulus by changing a different property. They are good candidates for integrating devices and structures that can self-accommodate to changing external conditions and behave as smart devices or systems.
Those Materials include: Thermal (thermo-chromic, thermo-electric), Mechanical (Shape Memory Alloys and Polymers, thermo-elastic), Magnetic (magneto-elastic, magneto-resistive, magneto-optic, ferrofluids, Ferromagnetic Shape Memory Alloys, etc.), Electric (photoelectric, advanced piezoelectric materials), Multiferroics, etc.
Ferromagnetic shape memory alloys (FSMAs)
FSMAs are magnetic metallic compounds undergoing a martensitic transformation and reaching a self-accommodated variant structure. They are of high technological interest as able to develop up to 10% strains as a function of applied magnetic field. Typical compositions include NiMn(Ga,Sb,In,Sn), FeNiGa(Al), CoNiGa(Al), etc.
Work at the BCMaterials is carried out in the following subjects:
- Development and optimization of high-performance FSMAs by precise tailoring their composition and substructure (training).
- Experimental and theoretical studies of the structure, phase transformation and functional properties.
- Development of FSMAs thin films for micro- and nano-actuator applications
Smart Polymers and composites
A responsive macromolecule changes its conformation and/or properties in a controllable, reproducible, and reversible manner in response to an external stimulus (solvent, pH, temperature, etc.). These changes can be used to create a large variety of smart devices. The good processability of most smart polymers facilitates their incorporation into devices and adds additional advantages (e.g. all plastic electronic/optical sensors).
Work at the BCMaterials is carried out in the following subjects:
- Shape memory polymers.
- Block copolymers for nanodot generation
- Hybrid Polymer/Inorganic systems for advanced applications like conductive polymers, non linear optics, selective complexation
- Active/Smart Hybrid surfaces for thin film sensors
Hybrid multiferroics (magnetoelectric) materials
Laminar or granular composites formed by a magnetostrictive and a piezoelectric material, either: Metal/ceramic (Metglas – PZT), Metal/polymer (Metglas/Terfenol – PVDF/Poliimide), or Oxide/polymer (Ferrrite – PVDF/Poliimide).The aim is to get a very large electric output from a low magnetic excitation to develop extremely sensitive sensors for ELF communications, energy harvesting, etc.
Advanced functional materials
New materials with outstanding properties are continuously appearing (see for instance graphene) in all fields of activity. There is impossible to take care of all of them, but some representative fields of research are already running and will be developed in the first stages of the BCMaterials activity. Those are:
Materials for energy
New materials for energy generation and storage constitute a topic of the greatest significance due to its great economic potential and social impact. Fuel cells, and specially the so-called SOFC´s (solid oxide fuel cells), are one of the most promising alternatives for the production of environmentally friendly energy. Chemical energy storage devices (batteries) and electrochemical capacitors (ECs) are among the leading technologies today, critically needed to enable the effective use of alternative energy sources such as solar and wind, and to allow the expansion of electrical or hybrid electrical vehicles. A fundamental understanding of the physical and chemical processes that take place in the electrodes, the electrolytes and specially their interfaces is need to design the next generation of high performance ECs. New separators and electrolytes with increased capacity and conductivity are needed to improve efficiency and the possibility of operating at high currents, but also new materials have to be design to increase service life and to reduce the size and the associated unitary cost.
Activity are devoted to the following subjects:
- Understanding the basis for the design and synthesis of new anodes and cathodes and cell chemistries.
- Characterization of physical, chemical and dynamic electrochemical properties controlling electrode surfaces and electrode-electrolyte interfaces.
- Theoretical modelling of electrode structure and design of electrochemical phenomena.
- Development of nanostructured electrolyte and electrode materials for SOFC’s, and new component materials for advanced lithium-based batteries and electrochemical capacitors.
- Preparation of the above materials as ultra-thin layers.
Materials for sensors and bio-sensors
Sensors, and specifically magnetic sensors, are nowadays earning an exceptional prominence in many technological areas such as personal electronics, automotive and transportation and bio-medicine. They are also of great importance in their traditional niche of applications: the industrial processes.
New, competitive sensors must be produced by microfabrication (MEMS) to benefit from the high sensing density and smooth interfacing with electronic circuitry, as well as low fabrication price and energy consumption. The research in this area must therefore seek for promising functional materials with outstanding sensing properties but also pay attention to the effects of scaling and the necessity to integration with microelectronic conditioning interfaces.
Research activity are focused on:
- Development of new magnetic thin films and multilayered structures for magneto-resistance and Magneto-Impedance ultra-sensitive magnetic field sensors.
- Integration of functional devices for detection of bio-medical nano-particles, and electronic compasses.
- Study of new magnetoelastic materials for sensing applications. In particular magnetoelastic sensors for on-line measuring of oil viscosity.
Materials for particle accelerators
Permanent and superconducting magnets are essential for the development of the 21st century accelerators. The LHC for instance counts about 1200 superconducting bending magnets, as well as about 400 focusing quadrupoles. Other parts of the accelerators, like ion sources, RF cavities and diagnostic and sensing systems, also require new and highly performing materials. The full instrument is under a large radiation dose that makes such materials to be specially designed to stand the exposure. This need for radiation resistant materials is shared with other modern technologies and in particular with fusion technology (ITER project) where the “first wall” technical requirements are specially demanding.
Research activity is carried out in collaboration with ESS Bilbao on:
- Permanent magnet design of bending and focusing elements
- Radiation damage on magnets and other elements for accelerators
- Sensing elements for the beam
Nanomagnetism
Nanoscale magnetic materials are the basis of a large number of devices and applications in many human activity fields, like Medicine, Electronics, Computer parts, Information storage, etc. Only a few of them can be explored at the starting of the BCMATERIALS.
Magnetic Nanoparticles for Biomedical and Industrial Applications
Magnetic Nano-Particles (MNP) have a diverse range of uses from magneto-rheological fluids, MRI contrast or hyperthermia in cancer therapy, to drug delivery. Such applications require the production of monodisperse nanoparticles with well-controlled size and composition, biocompatibility, proper functionalization, etc., in order to obtain the desired properties. Regarding hyperthermia essays, there is also a need for design and construction of equipment producing RF magnetic fields of high frequency and large amplitude, compatible with the legislation for the human body, proper targeting of the magnetic MNPs into the neoplastic tissue, “in situ” visualizing of the MNPs, etc.
Activity is devoted to the following subjects:
- Synthesis of MNP, either Chemical (inverse micelle, sol-gel, etc.), or Biological, by metal reducing micro-organisms
- Hyperthermia therapy studies for liver metastasis of colon-rectum cancer.
- Magneto-rheological fluids: synthesis, characterization, modeling and implementation as smart dampers.
Magnetic Nanostructures
New properties appear in magnetic materials as dimensions are reduced to a typical magnetic length scale, like domain wall width or exchange correlation length, that lie in the nanometer range. For this reason, artificially patterned nanostructures (top-down) and self assembled nanoparticle arrays (bottom-up) based magnetic materials have an increasing interest, from both fundamental and applied viewpoints.
Current activity is concentrated in the following areas:
- Fabrication and characterization of magnetic nanostructures.
- Granular thin films composed of magnetic nanoparticles embedded in a metallic or insulating matrix.
- Magnetic multilayer systems.
See also
External links
References
- ↑ "Tres nuevos centros de excelencia en neurociencia, materiales y polímeros". Deia.
- ↑ http://ciencia.elcorreo.com/tecnologia/2012-06-25/tres-nuevos-centros-investigacion-excelencia-20120625.html
- ↑ "Ikerbasque aprueba crear este año otros tres centros de investigación de excelencia". El País. Retrieved 29 March 2011.
Coordinates: 43°17′47″N 2°52′00″W / 43.2963°N 2.8666°W