BrainMap

Lucian Trupina

- INSTITUTUL NATIONAL DE CERCETARE - DEZVOLTARE PENTRU FIZICA MATERIALELOR BUCURESTI RA

Researcher

Web of Science ResearcherID: B-6802-2012

Expertise & keywords

Memristive multiferroic junctions Call name: P 2 - SP 2.1 - Proiect experimental - demonstrativ
PN-III-P2-2.1-PED-2021-0378 2022 - 2024

Role in this project:

Coordinating institution: INSTITUTUL NATIONAL DE CERCETARE - DEZVOLTARE PENTRU FIZICA MATERIALELOR BUCURESTI RA

Project partners: INSTITUTUL NATIONAL DE CERCETARE - DEZVOLTARE PENTRU FIZICA MATERIALELOR BUCURESTI RA (RO)

Affiliation:

Project website: https://infim.ro/en/project/memristive-multiferroic-junctions-mms/

Abstract:

Versatile multi-level memristive elements based on multiferroic tunnel junctions have outstanding features determined by the possibility to modulate the junction’s current by independently controlling the magnetization orientation of the ferromagnetic electrodes and the ferroelectric polarization of the tunnel barrier. The coupling of these magneto-electric properties is one of the most active field of research in materials sciences opening a large spectrum of technological applications from nonvolative memory, to elements in logic circuits, sensing devices, energy harvesting, biological synapses models in the emerging area of neuromorphic computing and artificial intelligence. Herein, we will demonstrate the multi-memristive spintronic states behavior of multiferroic tunnel junctions in elements with two terminals composed of nanoscale tunneling barrier consisting on organic ferroelectric films and for the first time of biomolecules, sandwiched between two different magnetic Heusler alloys electrodes. The realization of these resistive states – a transition from TRL2 to TRL3 level - will be controlled by the dependence of the tunneling current through this heterostructure on the electrical polarization of the ferroelectric film (the tunneling electroresistance) and on the relative orientation of the magnetization of the magnetic electrodes (the tunneling magnetoresistance). Moreover, a reciprocal influence between the electric and the magnetic properties can be realized by the control of the magneto-electric coupling at the interfaces using multifunctional effects associated to temperature or mechanical changes, i.e. the pyro- and piezo-electric properties of the ferroelectrics and the magneto-caloric, magneto-restrictive and the strong spin-polarization effects of the chosen compounds of the magnetic electrodes.

Controlling the electronic properties in heterostructures based on ferroelectric perovskites: from theory to applications Call name: P 4 - Proiecte Complexe de Cercetare de Frontieră
PN-III-P4-ID-PCCF-2016-0047 2018 - 2022

Role in this project:

Coordinating institution: INSTITUTUL NATIONAL DE CERCETARE - DEZVOLTARE PENTRU FIZICA MATERIALELOR BUCURESTI RA

Project partners: INSTITUTUL NATIONAL DE CERCETARE - DEZVOLTARE PENTRU FIZICA MATERIALELOR BUCURESTI RA (RO); INSTITUTUL NATIONAL DE CERCETARE - DEZVOLTARE PENTRU FIZICA MATERIALELOR BUCURESTI RA (RO); INSTITUTUL NATIONAL DE CERCETARE DEZVOLTARE PENTRU TEHNOLOGII IZOTOPICE SI MOLECULARE I N C D T I M (RO); UNIVERSITATEA POLITEHNICA DIN BUCURESTI (RO)

Affiliation: INSTITUTUL NATIONAL DE CERCETARE - DEZVOLTARE PENTRU FIZICA MATERIALELOR BUCURESTI RA (RO)

Project website: http://infim.ro/en/project/control-of-electronic-properties-in-ferroelectric-perovskite-heterostructures-from-theory-to-applications/

Abstract:

The main objective of the project is to obtain ferroelectric materials with controlled electronic properties at the same level as this properties are controlled in Si. This will be realized by hetero-valent doping, correlated with stress engineering and band gap engineering without affecting, as much as possible, the ferroelectric properties. The main objective is complex and ambitious because, up to date, there was no experimental demonstration that it possible to obtain n or/and p type conduction in epitaxial ferroelectrics. The successful achievement of this objective will open a new domain, that of ferroelectric electronics or ferrotronics, by producing electronic devices of p-n homo-junction type or junction transistors with ferroelectric materials. Two types of materials are envisaged, namely lead titanate-zirconate (PZT with tetragonal structure and a mixed bismuth ferrite (BFO) with bismuth chromit (BCO). In the first case the heterovalent doping will be studied on Pb or Zr/Ti sites with the aim to obtain n and p type conduction. The final goal is to produce a p-n homo-junction based on epitaxial PZT films. In the second case band gap engineering will be tested by varying the Fe/Cr content, and the dominant conduction mechanism will be identified, the goal being to use the material in photovoltaic applications. The activities will contain: theoretical studies regarding the relation between dopants, electronic properties and the ferroelectricity, including self-doping effects or electrostatic doping; target preparation for deposition of thin films; epitaxial growth of the film; characterization activities of the structure and physical properties. Not only classic doping in the target is envisaged but also doping during the epitaxial growth. The consortium is composed of 4 teams from three different institutions, including a number of 14 young researchers full time equivalent.

PZT based piezo elements for rocket propelled grenade ordnance Call name: P 2 - SP 2.1 - Proiect experimental - demonstrativ
PN-III-P2-2.1-PED-2019-3466 2020 - 2022

Role in this project:

Coordinating institution: INSTITUTUL NATIONAL DE CERCETARE - DEZVOLTARE PENTRU FIZICA MATERIALELOR BUCURESTI RA

Project partners: INSTITUTUL NATIONAL DE CERCETARE - DEZVOLTARE PENTRU FIZICA MATERIALELOR BUCURESTI RA (RO)

Affiliation: INSTITUTUL NATIONAL DE CERCETARE - DEZVOLTARE PENTRU FIZICA MATERIALELOR BUCURESTI RA (RO)

Project website: https://infim.ro/en/project/pzt-based-piezo-elements-for-rocket-propelled-grenade-ordnance/

Abstract:

The defense industry has always attracted substantial interest and funding with the main purpose to serve as a deterrent against conflicts. Within the North Atlantic Treaty Organization (NATO) strategy the Eastern European countries are urged to modernize their military capabilities. Within this context we have been approached by Mija Mechanical Plant S.A., a branch of Romarm S.A., a company which includes the most important factories from Romanian defense industries and is the largest national supplier for military ordnance and an important player on the international market. Their main focus is to modernize the piezoelectric elements used in the final stage of the rocket propelled grenades (RPG) for anti-tank and high explosive rounds.

The focus is to upgrade the piezo elements from the current BaTiO3 materials to a high performance Lead Zirconate Titanate (PZT) based technology. The BaTiO3 piezoelectric elements present o series of drawbacks compared to the PZT as they have significantly smaller piezoelectric effect, phase transitions in the required working range, less stable morphotropic phase boundaries leading to low life time manifested in depolarization. On top of their intrinsic material limitation, the BaTiO3 piezo elements used for RPG manufacturing are scarcely available on the NATO sanctioned markets making this technological upgrade also a strategic desiderate.

Therefore, the main objective of this project is to develop a PZT based piezo element for RPG construction designed to fulfill the strict requirements of the manufacturer. The project will focus on the production, characterization and the optimization of high quality PZT based materials starting from compositions our research group has extensive experience with. The end product will be a functional prototype of the required piezo element protected by a patent.

Multifunctional dielectric materials produced by spark plasma sintering for passive microwave devices Call name: P 2 - SP 2.1 - Proiect experimental - demonstrativ
PN-III-P2-2.1-PED-2019-3351 2020 - 2022

Role in this project:

Coordinating institution: INSTITUTUL NATIONAL DE CERCETARE - DEZVOLTARE PENTRU FIZICA MATERIALELOR BUCURESTI RA

Project partners: INSTITUTUL NATIONAL DE CERCETARE - DEZVOLTARE PENTRU FIZICA MATERIALELOR BUCURESTI RA (RO)

Affiliation: INSTITUTUL NATIONAL DE CERCETARE - DEZVOLTARE PENTRU FIZICA MATERIALELOR BUCURESTI RA (RO)

Project website: https://infim.ro/project/master-2/

Abstract:

Low-loss temperature stable dielectric materials have been used to decrease the cost and size of the passive microwave devices (eg. filters, oscillators, multiplexers, antennas). The main objective of the project is to exploit the versatility of the spark plasma sintering (SPS) technique in order to prepare Zr1-xSnxTiO4 (ZST) solid solutions with various shapes whose multifunctional properties set the ground for development of the new generation of high performance microwave devices. Even though has several advantages, SPS can produce a lot of oxygen vacancies in oxide materials and such defects increase the dielectric loss. In order to overcome this drawback, as-sintered sample will be ex-situ annealed in air or oxygen atmosphere. Apart of usual structural and morphological characterizations, the extrinsic contribution to the losses will be investigated by microwave spectroscopy and terahertz time-domain spectroscopy. Through the analysis of the “synthesis - microstructure – properties” cycle, the technology suitable for fabrication of “zero-porosity” ZST ceramics with low dielectric loss in microwave domain will be developed. The targeted results would allow achieving of materials with multifunctional properties with a breakthrough potential in terms of efficiency and cost-effectiveness of the passive microwave devices required in the future monitoring and communications systems.

NEW METHODS OF DIAGNOSIS AND TREATMENT: CURRENT CHALLENGES AND TECHNOLOGIC SOLUTIONS BASED ON NANOMATERIALS AND BIOMATERIALS Call name: P 1 - SP 1.2 - Proiecte complexe realizate in consorții CDI
PN-III-P1-1.2-PCCDI-2017-0062 2018 - 2021

Role in this project:

Coordinating institution: INSTITUTUL NATIONAL DE CERCETARE - DEZVOLTARE PENTRU FIZICA MATERIALELOR BUCURESTI RA

Project partners: INSTITUTUL NATIONAL DE CERCETARE - DEZVOLTARE PENTRU FIZICA MATERIALELOR BUCURESTI RA (RO); INSTITUTUL NATIONAL DE CERCETARE-DEZVOLTARE IN DOMENIUL PATOLOGIEI SI STIINTELOR BIOMEDICALE "VICTOR BABES" (RO); UNIVERSITATEA DE MEDICINA SI FARMACIE "CAROL DAVILA" (RO); UNIVERSITATEA DE MEDICINA SI FARMACIE "GRIGORE T. POPA" DIN IAŞI (RO); INSTITUTUL NATIONAL DE CERCETARE - DEZVOLTARE CHIMICO - FARMACEUTICA - I.C.C.F. BUCURESTI (RO); INSTITUTUL NATIONAL DE CERCETARE DEZVOLTARE PENTRU TEHNOLOGII IZOTOPICE SI MOLECULARE I N C D T I M (RO); UNIVERSITATEA TRANSILVANIA BRASOV (RO)

Affiliation: INSTITUTUL NATIONAL DE CERCETARE - DEZVOLTARE PENTRU FIZICA MATERIALELOR BUCURESTI RA (RO)

Project website: http://infim.ro/en/project/sanomat/

Abstract:

The project will develop novel conceptual and functional solutions of biomedical devices for treatment, reinforcement/repair/replacement (of human tissues) and diagnosis based on nanostructured and/or biocompatible materials, with high attractivity and certain potential for technology transfer to industry. The experience of the interdisciplinary consortium will allow a passage from concepts of nanomaterials and biomaterials with extended and/or complementary functional features to implementation to new biomedical applications of great interest: (i) antitumoral therapeutic systems (by localized magnetic hyperthermia, photodynamic therapy and drug delivery); (ii) biocompatible compounds with enhanced antimicrobial efficacy; (iii) stent or vein/arterial filters implants based on ferromagnetic shape-memory alloys (with the advantage of repositioning without the need of new invasive interventions); (iv) personalized bone regenerative implants (i.e. porous ceramic scaffolds for bone tissue engineering; dental implants with rapid osseointegration); (v) (bio)sensors for monitoring the bioavailability of pharmaceutical compounds and detecting the reactive oxygen species and their biologic effect; and (vi) correlation of physico-chemical properties with clinical investigations for two types of aerosols (salt particles and essential oils), and their prospective coupling with possible synergistic effects. The synergic development of the institutional capacity of the project partners will be achieved by: creating new jobs and purchasing new equipment and software, providing technical/scientific assistance to the emerging institutions, initiating and fostering collaborations with partners from industry in view of technology transfer, and increasing the international visibility of the involved institutions by capitalizing on the obtained research results. The project will create the core of the first national cluster in the field of healthcare technologies.

Technologic paradigms in synthesis and characterization of variable dimensionality systems Call name: P 1 - SP 1.2 - Proiecte complexe realizate in consorții CDI
PN-III-P1-1.2-PCCDI-2017-0152 2018 - 2021

Role in this project:

Coordinating institution: INSTITUTUL NATIONAL DE CERCETARE - DEZVOLTARE PENTRU FIZICA MATERIALELOR BUCURESTI RA

Project partners: INSTITUTUL NATIONAL DE CERCETARE - DEZVOLTARE PENTRU FIZICA MATERIALELOR BUCURESTI RA (RO); INSTITUTUL NATIONAL DE CERCETARE-DEZVOLTARE PENTRU TEHNOLOGII CRIOGENICE SI IZOTOPICE - I.C.S.I. RAMNICU VALCEA (RO); UNIVERSITATEA DE VEST TIMISOARA (RO); INSTITUTUL NATIONAL DE CERCETARE- DEZVOLTARE PENTRU MICROTEHNOLOGIE - IMT BUCURESTI INCD (RO); INSTITUTUL NATIONAL DE CERCETARE-DEZVOLTARE PENTRU FIZICA TEHNICA-IFT IASI (RO)

Affiliation: INSTITUTUL NATIONAL DE CERCETARE - DEZVOLTARE PENTRU FIZICA MATERIALELOR BUCURESTI RA (RO)

Project website: http://infim.ro/project/vardimtech/, http://infim.ro/project/vardimtech-en

Abstract:

Last decades brought a considerable development of technologies based on ordered systems. Starting with semiconductor physics and photovoltaics, technologies soon evolved towards the utilisation on large scale of thin films and of surface / interface properties. Example go nowadays from data storage and readout (electrostatic or magnetic memories, giant magnetoresistance) to catalysis, gas sensors or photocatalysis (surface phenomena), and towards interfaces with biological matter (biosensors, templates for tissue reconstruction, interfaces between biological electrical signals and microelectronics). In Romania, crystal growth is performed since half a century; nevertheless, during the last years these activities fade out and need to be seriously reinforced, especially with the advent of new laser and detector technologies required by the Extreme Light Infrastructure facilities. Also, surface science started to be developped seriously only during the last decade, together with techniques involving self-organized nanoparticles, nanoparticle production etc. The main goal of this Project is to gather the relevant experience from the five partners, namely the experience in crystal growth from the University of Timișoara, with the surface science, nanoparticle and nanowire technologies developped by NI of Materials Physics, the cryogenic and ultrahigh vacuum techniques provided by the NI for Cryogenic and Isotopic Technologie, and the experience in ordered 2D systems (graphene and the like) owned by the NI for Microtechnologies (IMT). This common agenda will result in a coherent fostering of technologies relying on ordered systems of variable dimensionalities: 0D i.e. clusters or nanoparticles, including quantum dots; 1D i.e. free and supported nanowires and nanofibers; 2D: surfaces, interfaces and graphene-like systems; and 3D crystals of actual technological interest, together with setting up new ultrahigh vacuum, surface science and electron spectroscopy techniques.

Integration of new and improved MAterials for Smart millimeTER-wave Sensors Call name: P 3 - SP 3.2 - Proiecte ERA.NET
M.ERANET-3194-MASTERS 2016 - 2019

Role in this project:

Coordinating institution: INSTITUTUL NATIONAL DE CERCETARE - DEZVOLTARE PENTRU FIZICA MATERIALELOR BUCURESTI RA

Project partners: INSTITUTUL NATIONAL DE CERCETARE - DEZVOLTARE PENTRU FIZICA MATERIALELOR BUCURESTI RA (RO)

Affiliation: INSTITUTUL NATIONAL DE CERCETARE - DEZVOLTARE PENTRU FIZICA MATERIALELOR BUCURESTI RA (RO)

Project website: http://infim.ro/en/project/integration-of-new-and-improved-materials-for-smart-millimeter-wave-sensors/

Abstract:

The MASTERS project is focusing on innovative solutions for the improvement, above the current state-of-the-art, of both security and power consumption of millimeter-wave sensors, by exploiting the permitivity agility of ferroelectric materials. Indeed, the integration of these intelligent and functional materials in practical devices will meet the current requirements for highly reconfigurable, integrated, safe, efficient and low power-consuming devices. The final goal of the project is the design and realization of original on-chip reconfigurable sensors as practical and efficient demonstrators for industrial applications, as a first step toward the establishment of innovative and highly-efficient market-oriented devices. Thanks to the structural, technological advantages and background of the MASTERS multi-national consortium and the expertise of the industrial partner, the project will create smart and user friendly solutions for sensing devices.

Investigations on advanced dielectric materials and structures in Terahertz and millimeter waves Call name: Exploratory Research Projects - PCE-2012 call
PN-II-ID-PCE-2012-4-0654 2013 - 2016

Role in this project:

Coordinating institution: INSTITUTUL NATIONAL DE CERCETARE - DEZVOLTARE PENTRU FIZICA MATERIALELOR BUCURESTI RA

Project partners: INSTITUTUL NATIONAL DE CERCETARE - DEZVOLTARE PENTRU FIZICA MATERIALELOR BUCURESTI RA (RO)

Affiliation: INSTITUTUL NATIONAL DE CERCETARE - DEZVOLTARE PENTRU FIZICA MATERIALELOR BUCURESTI RA (RO)

Project website: http://www.infim.ro/node/4190

Abstract:

At the present, terahertz technology is certainly one of the most dynamic research fields with wide variety of applications: terabit wireless communication, spectroscopy, biology, medical sciences, food control, security systems, etc. The project aims to investigate advanced conventional as well as structured materials in Terahertz and millimeter wave range. On one hand, highly accurate characterization methods of complex perovskite dielectrics (bulk and thin films) with high values of the product between the quality factor and the frequency will be developed for millimeter wave and Terahertz range. The application of development methods to measure ferroelectric perovskites in Terahertz range is very important for such applications as tunable photonic crystal filters. On the other hand, numerical and experimental investigations on structured materials will allow the study of the Terahertz spoof surface plasmon-polaritons in new complex geometries. The electromagnetic simulation, fabrication and characterization of the proposed materials and structures will benefit of recent acquisitioned state-of-the-art equipment in the host institution. The final outcome of the project will consist in solution for an improved controlled of the electromagnetic radiation in millimeter wave and Terahertz range.

High temperature, high stability, low cost evaporation cells for molecular beam epitaxy Call name: Joint Applied Research Projects - PCCA-2011 call, Type 2
PN-II-PT-PCCA-2011-3.2-0767 2012 - 2016

Role in this project:

Coordinating institution: INSTITUTUL NATIONAL DE CERCETARE - DEZVOLTARE PENTRU FIZICA MATERIALELOR BUCURESTI RA

Project partners: INSTITUTUL NATIONAL DE CERCETARE - DEZVOLTARE PENTRU FIZICA MATERIALELOR BUCURESTI RA (RO); INSTITUTUL NATIONAL DE CERCETARE DEZVOLTARE PENTRU TEHNOLOGII IZOTOPICE SI MOLECULARE I N C D T I M (RO); BRAVA 2000 S.R.L. (RO)

Affiliation: INSTITUTUL NATIONAL DE CERCETARE - DEZVOLTARE PENTRU FIZICA MATERIALELOR BUCURESTI RA (RO)

Project website: http://www.infim.ro/projects/celule-de-evaporare-la-temperaturi-mari-stabilitate-ridicata-si-cost-redus-pentru-depuneri

Abstract:

Evaporation cells based on a new heating principle will be designed, fabricated and tested. This heating principle is based on direct resistive heating of two concentric tubes made on a refractory metal (Ta, Mo, W), with thin walls (0.1-0.2 mm), subject to a high electrical current (60-100 A). The inner pipe contains the material to be evaporated. The outer pipe, which also warms up, acts at the same time as a thermal screen for the inner pipe: as a consequence, higher temperatures are achieved in the inner part and also a higher amount of power is dissipated inside the inner pipe. The warming up to very high temperatures (over 2000 C) proceeds in a few tens of seconds, to be compared with several tens of minutes in standard evaporation cells where a crucible is warmed by using a W filament. Also, a precise temperature calibration may be obtained as function of the heating current only, whereas in conventional cells thermocouples are used. These thermocouples require additional vacuum current feedthroughs and also their thermal contact to the crucible may be problematic. A third advantage of the new principle is its relative low cost, based on the fact that the only expensive parts are the refractory material pipes. A new concept (dismountable assembly) will be developed also for the water cooling of the cell, whereas a single high current vacuum feedthrough is sufficient. One anticipates easy and fast manufacture of such devices, resulting in low delivery terms, as compared with 3-6 months for the actual evaporators. The estimated market is of some 500-1000 units in the European Community, whereas the stipulated benefit is of 5000 Euro per unit. The project will (i) implement the new heating principle; (ii) implement the new water cooling principle; (iii) achieve accuracte temperature calibration; (iv) demonstrate the ability to evaporate at high temperature, especially of metals that are usually evaporated by electron bombardment: Ti, Cr, V, Zr, Nb.

Effect of interfaces on charge transport in ferroic/multiferroic heterostructures Call name: Complex Exploratory Research Projects - PCCE-2011 call
PN-II-ID-PCCE-2011-2-0006 2012 - 2016

Role in this project:

Coordinating institution: National Institute of Materials Physics

Project partners: National Institute of Materials Physics (RO); National Institute of Materials Physics (RO); National Institute of Materials Physics (RO); National Institute of Materials Physics (RO); National Institute of Materials Physics (RO); Alexandru Ioan Cuza University (RO)

Affiliation: National Institute of Materials Physics (RO)

Project website: http://www.infim.ro/projects/effect-interfaces-charge-transport-ferroelectricmultiferroic-heterostructures

Abstract:

The main objective of the project is to perform a detailed study of interfaces and their effect on the charge transport properties in a number of well defined artificial multiferroic structures. Charge transport is beneficial in some cases, for example in tunnel junctions, but can be detrimental in other cases, as for example devices based on magnetoelectric effect or in capacitor like structures. In all cases, at least the interfaces with the metallic electrodes are involved in charge transport, but other interfaces can be also involved if multilayer structures are used. The study will be performed on thin films and/or nanostructures, therefore a significant influence of interfaces on the electronic and ionic charge transport is expected. The start will be from simple capacitor-like structures, to elucidate the problem of electrode interfaces in the case of various ferroic oxides. Further on charge transport in relation with interfaces will be studied in mode complex, multilayer structures with possible applications in tunel junctions, diodes or field effect devices.

The project involves 6 research teams from 2 host institutions, one of which is the National Institute of Materials Physics from Bucharest-Magurele, and the other one is the Alexandru Ioan Cuza University (UAIC) from Iassy. The composition of the teams is a mixes experienced researchers with excellent track records regarding preparation, characterization and modelling of advanced multifunctional materials including oxides, and young scientists at the beginning of their carriers. Some 12 PhD thesis are expected to start during the project. The project is expected to have a major impact not only at the basic science level, reflected by publications in high ranking journals, but also at the level of applied research, as for example manipulation of charge transport through designing specific interfaces or developement of new oxide architectures for ferroelectric field effect controlled of spin currents.

Interplay between superconductivity and magnetism and superconducting order parameter symmetry in pnictide superconductors. Call name: Exploratory Research Projects - PCE-2011 call
PN-II-ID-PCE-2011-3-1028 2012 - 2016

Role in this project:

Coordinating institution: NSTITUTUL NATIONAL DE CERCETARE DEZVOLTARE PENTRU FIZICA MATERIALELOR

Project partners: NSTITUTUL NATIONAL DE CERCETARE DEZVOLTARE PENTRU FIZICA MATERIALELOR (RO)

Affiliation: NSTITUTUL NATIONAL DE CERCETARE DEZVOLTARE PENTRU FIZICA MATERIALELOR (RO)

Project website: http://www.infim.ro/NationalProjects/pce1028_2011/

Abstract:

FeAs based compounds are a new class of superconductors that have extremely interesting properties that may even allow them to become technological materials. When taken in the context of the high-Tc oxides, they present the hope that perhaps some clue to exotic superconductivity may be more clearly manifest in the FeAs system and will reveal details of pairing mechanism and help the development of the theory for the copper oxide systems. Also Fe2As2 further emphasize that superconductivity is a rather ubiquitous, low temperature ground state for metals and even semimetals. Despite the huge experimental effort, the detailed properties of these systems are only beginning to be revealed. Is the main objective of the present project to shade more light into the Cooper pairing mechanism and into the symmetry of the order parameter by studies under hydrostatic pressure and as function of systematic doping. Will be further rewarding if we will, as a side effort, manage to enhance superconducting transition temperature.

FILE DESCRIPTION	DOCUMENT
List of research grants as project coordinator
List of research grants as partner team leader
List of research grants as project coordinator or partner team leader
Significant R&D projects for enterprises, as project manager
R&D activities in enterprises
Peer-review activity for international programs/projects