Jan Van HerleNé à Anvers, Belgique, 1966. En Suisse depuis 1983. Naturalisé Suisse en 2004 par persuasion de la culture suisse démocratique et participative 'bottom-up'. Pas de double nationalité. Conseiller communal durant 2 mandats de 5 ans de 2006 à 2016.
1987 : Chimiste de l'Université de Bâle (CH).
1988 : Post-grade informatique de l'Ecole d'Ingénieurs de Bâle.
1989 : Stage industriel chez ABB à Baden (CH).
1990-1993 : Thesè EPFL
1994-1995 : Postdoc au Japon (Tokyo).
1996-2000 : Chercheur à l'EPFL, Dpt. Chimie, responsable de groupe.
1998-2000 : Master en Energy Technology, EPFL.
2000 : Cofondateur de HTceramix SA (EPFL spin-off), à Yverdon (actuellement 12 employés). La maison mère SOLIDpower en Italie, qui a acheté notre technologie en 2007, emploie 250 personnes et a levé 70 MCHF.
2000-2012 : 1er Assistant et chargé de cours en STI-IGM. Promu à MER en 2008.
2013-présent: MER responsable d'unité.
Output : 135 publications, 120 papiers de conférence, 15 théses de doctorat, 4 thèses en cours, 37 thèses de master. Facteur h-42, >5000 citations.
Fonds levés jusqu'à présent >19 MCHF.
5 langues couramment (néerlandais, français, allemand (y.c. suisse-allemand), anglais, espagnol).
Manuel Alexandre PouchonResearcher in experimental and theoretical materials science, specializing in the development of nuclear fuels since 1997, and structural materials for nuclear reactors since 2004. Presently leading nuclear materials lab (LNM) and the advanced nuclear materials (ANM) group and programme at the Paul Scherrer Institute (PSI) in Switzerland. The applicability of different material candidates in advanced nuclear reactors is researched. Especially different aspects of radiation damage are investigated. For this purpose the concept of sample miniaturization is applied and further developed. Recently leading a new activity in particle fuel production and application. Previously working for the FUJI project at PSI, where different nuclear fuel forms for fast reactors were produced, characterized and finally irradiated in reactor. This work was performed in collaboration with the Japan Nuclear Cycle Development Institute (JNC) and Nuclear Research & consultancy Group (NRG) in the Netherlands. Previously an International Fellow at JNC investigating the thermal conductivity, sintering behaviour, and mechanical interaction of ceramic-sphere fuel beds; this includes the use of finite element methods for simulating various behaviours. Previously at the Paul Scherrer Institute (PSI) and for the Inert Matrix Fuel Project for burning plutonium in light water reactors, investigating the thermal conductivity and the diffusion and solubility of fission products of a zirconia-based non-fertile matrix.
Christos ComninellisChristos Comninellis, of Greek origin, born in 1945, received his Bachelor of Science in chemistry (distinction with honor) in 1970 from the University of Alexandria.
From 1971 to 1975, he worked as a chemist at the Institute of chemical engineering at the EPFL, where he achieved his PhD in technical sciences in 1979 for his research on the electrochemical fluorination of organic compounds in anhydrous hydrogen fluoride.
Appointed professor in 1996, he teaches at the Faculty of Basic Sciences (FSB) of the Swiss Federal Institute of Technology, Lausanne (EPFL)
Applied Chemistry.
Transport Phenomena.
Chemical and Electrochemical Technologies Related to the Environment.
Electrochemical Engineering.
He also holds a teaching position at the Haute Ecole Valaisanne Sion (HEVs).
His research work is focused on environmental electrochemistry, electrocatalysis, fuel cell and electrochemical promotion in catalysis. An applied research for the utilization of electrochemical techniques in industry for the protection of the environment is a constant concern within his activities. As a result, the collaboration with the industry enabled the development of oxidation processes with regeneration of the oxidant using a new type of bipolar electrochemical reactor.
Christos Comninellis has published over 170 scientific papers, directed 17 doctoral theses and holds 14 patents. He has participated in over 130 international symposia, giving five plenary lectures during the last five years. He has been president of the Evaluation Committee of the FSB since the beginning of 2004 and is member of the jury of the EPFL prize for outstanding PhD-thesis.
Nava SetterNava Setter completed MSc in Civil Engineering in the Technion (Israel) and PhD in Solid State Science in Penn. State University (USA) (1980). After post-doctoral work at the Universities of Oxford (UK) and Geneva (Switzerland), she joined an R&D institute in Haifa (Israel) where she became the head of the Electronic Ceramics Lab (1988). She began her affiliation with EPFL in 1989 as the Director of the Ceramics Laboratory, becoming Full Professor of Materials Science and Engineering in 1992. She had been Head of the Materials Department in the past and more recently has served as the Director of the Doctoral School for Materials.
Research at the Ceramics Laboratory, which Nava Setter directs, concerns the science and technology of functional ceramics focusing on piezoelectric and related materials: ferroelectrics, dielectrics, pyroelectrics and also ferromagnetics. The work includes fundamental and applied research and covers the various scales from the atoms to the final devices. Emphasis is given to micro- and nano-fabrication technology with ceramics and coupled theoretical and experimental studies of the functioning of ferroelectrics.
Her own research interests include ferroelectrics and piezoelectrics: in particular the effects of interfaces, finite-size and domain-wall phenomena, as well as structure-property relations and the pursuit of new applications. The leading thread in her work over the years has been the demonstration of how basic or fundamental concepts in materials - particularly ferroelectrics - can be utilized in a new way and/or in new types of devices. She has published over 450 scientific and technical papers.
Nava Setter is a Fellow of the Swiss Academy of Technical Sciences, the Institute of Electrical and Electronic Engineers (IEEE), and the World Academy of Ceramics. Among the awards she received are the Swiss-Korea Research Award, the ISIF outstanding achievement award, and the Ferroelectrics-IEEE recognition award. In 2010 her research was recognized by the European Union by the award of an ERC Advanced Investigator Grant. Recently she received the IEEE-UFFC Achievement Award (2011),the W.R. Buessem Award(2011), the Robert S. Sosman Award Lecture (American Ceramics Society) (2013), and the American Vacuum Society Recognition for Excellence in Leadership (2013).
Cyril CayronMes recherches: J'ai travaillé comme microscopiste/cristallographe/métallurgiste sur des projets très variés comme les aciers pour le nucléaire, les alliages titane et nickel pour l'aéronautique, les interconnections en cuivre pour la microélectronique, les piles à combustible haute et basse température, le silicium photovoltaïque hétérojonction et monolike, les batteries au lithium à base de LiFePO4 et silicium. Derrière la plupart de ces sujets de recherche appliquée se cachent des problèmes de recherche fondamentale comme celui lié aux transformations de phases. J'ai donc été amené à travailler sur ce sujet passionnant et j'ai pu démontrer que les variants cristallographiques générés par des transitions structurales forment une structure algébrique de groupoïde. Ces travaux ont mené au développement du logiciel de reconstruction des grains parents à partir de données EBSD appelé ARPGE et distribué dans plus de 20 pays. En 2013-2015 j'ai proposé un nouveau modèle cristallographique pour les transformations martensitiques fcc-bcc dans les aciers, comme une alternative à la théorie phénoménologique de la transformation martensitique. Ce modèle a été depuis étendu aux transformations fcc-hcp (type cobalt), bcc-hcp (type titane) et bcc-fcc (type laiton), ainsi qu’à differents modes de maclage mécanique dans les métaux fcc et hcp. Ce modèle à sphères dures montre que la transformation implique une «distorsion angulaire», forme plus générale que le cisaillement. Le modèle prévoit la possibilité que le plan d’interface de certaines macles mécaniques ne soit pas un plan invariant. Un tel cas de maclage « exotique » a été observé expérimentalement par EBSD en 2017 dans un monocristal de magnésium pur. Je travaille maintenant à définir de manière algébrique les concepts de variants (orientation, distortion, correspondance), et sur les types de macles mécaniques (I, II, et d'autres oubliés des théoriques classiques). Mon parcours : 2014-maintenant: Collaborateur scientifique à l'EPFL/LMTM, Neuchâtel, Suisse. J'aide le professeur Roland Logé dans ses travaux de recherche sur les liens entre les fortes déformations, les textures, les tailles de grains et les transformations de phases (diffusives et displacives). Je suis en charge de la salle de métallographie et des caractérisations SEM, EDS, EBSD, TEM, HRTEM. Je codirige trois thèses (Annick Baur, Margaux Larcher, Céline Guidoux). Je suis reviewer pour Acta Mater., Scripta Mater., Acta Cryst., J. Appl. Cryst., Mater. Charact., etc. 2000-2014: Ingénieur de recherche et responsable du groupe Nanocaractérisation, CEA/LITEN, Grenoble, France. 2012 : Habilitation à Diriger des Recherches (HDR). 1996-2000: Thèse sur l'étude par microscopie électronique de composites à matrice aluminium. Directeur de thèse Philippe Buffat, CIME, EPFL, Lausanne, Suisse. J'ai pu montrer un lien cristallographique entre différentes phases des alliages 2xxx et 6xxx et proposer pour la première fois une structure complète pour la phase beta prime des nanoprécipités. 1995-1996: Scientifique du contingent, travail sur les écrans électrochromes, COGIDEV, Rueil-Malmaison, France, fondé par M. André Giraud, ancien ministre de la défense et ancien ministre de l’industrie. 1992-1995: Ecole Nationale Supérieure des Mines de Nancy, France
Dragan DamjanovicDragan Damjanovic received BSc diploma in Physics from the Faculty of Natural Sciences and Mathematics, University of Sarajevo, in 1980, and PhD in Ceramics Science from the Department of Materials Science and Engineering, College of Earth and Mineral Sciences, the Pennsylvania State University (PSU) in 1987. From 1988 to 1991 he was a research associate in the Materials Research Laboratory at the PSU. He joined the Ceramics Laboratory, Department of Materials Science and Engineering, Ecole polytechnique fédérale de Lausanne in 1991. He is currently a "professeur titulaire", heads the Group for Ferroelectrics and Functional Oxides at the Institute of Materials and teaches undergraduate and graduate courses on structure and electrical properties of materials. The research activities include fundamental and applied investigations of piezoelectric, ferroelectric and dielectric properties of a broad class of materials.
Alfredo PasquarelloAlfredo Pasquarello effectue ses études en physique à l'Ecole normale supérieure de Pise et à l'Université de Pise et obtient leurs diplômes respectifs en 1986. Il obtient le titre de Docteur ès sciences à l'EPFL en 1991 avec une thèse portant sur les transitions à plusieurs photons dans les solides. Ensuite, il effectue des recherches post-doctorales aux Laboratoires Bell (Murray Hill, New Jersey) sur les propriétés magnétiques des fullerènes de carbone. En 1993, il rejoint l'Institut romand de recherche numérique en physique des matériaux (IRRMA), où sa recherche porte sur des méthodes de simulation ab initio. En 1998, le Prix Latsis de l'EPFL lui est decerné pour son travail de recherche portant sur les matériaux à base de silice désordonnée. Bénéficiant de plusieurs subsides du Fonds National, il constitue ensuite sa propre équipe de recherche à l'IRRMA. En juillet 2003, il est nommé Professeur en Physique théorique de la matière condensée à l'EPFL. Actuellement, il dirige la Chaire de simulation à l'échelle atomique.
Paul MuraltPaul Muralt received a diploma in experimental physics in 1978 at the Swiss Federal Institute of Technology ETH in Zurich. He accomplished his Ph.D. thesis in the field of commensurate-incommensurate phase transitions at the Solid State Laboratory of ETH. In the years 1984 and 1985 he held a post doctoral position at the IBM Research Laboratory in Zurich where he pioneered the application of scanning tunneling microscopy to surface potential imaging. In 1987, after a stay at the Free University of Berlin, he joined the Balzers group in Liechtenstein. He specialized in sputter deposition techniques, and managed since 1991 a department for development and applications of Physical Vapor Deposition and PECVD processes. In 1993, he joined the Ceramics Laboratory of EPFL in Lausanne. AS group leader for thin films and MEMS devices, he specialized in piezoelectric and pyroelectric MEMS with mostly Pb(Zr,Ti)O3 and AlN thin film. His research interests are in thin film growth in general, and more specifically in property assessment of small ferroelectric structures, in integration issues of ferroelectric and other polar materials, property-microstructure relationships, and applications of polar materials in semiconductor and micro-electro-mechanical devices. More recently he extended his interests to oxide thin films of ionic conductors. The focus in piezoelectric thin films was directed towards AlN-ScN alloys. He gives lectures in thin film processing, micro fabrication, and surface analysis. He authored or co-authored more than 230 scientific articles. He became Fellow of IEEE in 2013. In 2005, he received an outstanding achievement award at the International Symposium on Integrated Ferroelectrics (ISIF), and in 2016 the B.C. Sawyer Memorial award.
Chairman of the International Workshops on Piezoelectric MEMS(http://www.piezomems2011.org/)