Marco Cantoni1982-1988, Diploma course in Experimental Physics (certificate, 28.10.88)ETHZ Faculty IX MATHEMATICS and PHYSICS, Diploma Thesis: "Abweichungen von der ikosaedrischen Symmetrie in Al-Cu-Li Quasikristallen", Advisor: Prof. H.-U. Nissen 1989-1993, Ph.D. in Experimental Physics (certificate, 23.8.94) ETHZ Physics Department, Laboratory of Solid State Physics, Ph. D. Thesis No. 10421, Title: "Elektronenmikroskopische Untersuchung der Realkristallstruktur epitaktischer Schichten von Supraleitern des Typs SEBa2Cu3O7-x auf (100)-SrTiO3" Advisors: Prof. H.R. Ott, Prof. H. U. Nissen. 1994-1996,ETH Zürich,Material Science Department, Non-Metallic Materials, Prof. L. Gauckler: Microstructure characterisation of high-tech ceramic materials by means of SEM, TEM and atomic force microscopy: superconductor thick films (Bi-2212 on Ag) and solid oxide fuel cells (ZrO2, CeO2). 1996-1998, National Institute for Research in Inorganic Materials NIRIM, Japan Group for Special Research, Prof. S. Horiuchi: TEM of Bi-2223/Ag Tapes, Application of Imaging Plates (IP) in High Voltage TEM, Cryo-Lorentz-TEM of Superconducting Materials (Observation of Flux-Lines) 1998-2000, Ecole polytechnique fédéral de Lausanne, EPFL-CIME Centre interdépartemental de microscopie électronique CIME, Prof. P.A. Buffat: Projet 125, PPO II (programme prioritaire optique): Characterization of materials and devices for optic and optoelectronic applications by electron microscopy. 2001-2003, Ecole polytechnique fédéral de Lausanne, EPFL STI IMX LCCeramics Laboratory, Prof. Nava Setter Characterisation of ferroelectric materials, transmission electron microscopy of relaxor ferroelectric materials 2004, University of Geneva, Physics Department, Condensed matter Physics Group of Prof. R. Flükiger, TEM of Multifilament Nb3Sn superconducting wires, in collaboration with EPFL-CIME Since 1.11.04, EPFL-SB-CIME
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.
Jan Van HerleBorn in Antwerp, Belgium. In Switzerland since 1983. Became Swiss citizen in 2004 out of conviction of principles of democracy and bottom-up participation. No double nationality. Village Council Member for 2 five-year mandates in 2006-2016.
1987 : Chemist from Basel University (CH).
1988 : Post-graduate IT diploma from Basel Engineering School.
1989 : Industry internship ABB Baden (CH).
1990-1993 : PhD Thesis EPFL, on Solid Oxide Fuel Cell cathode reaction mechanisms.
1994-1995 : Japanese Postdoctoral Fellowship in Tsukuba, Japan, on ceramic powders.
1995-2000 : Researcher at EPFL, Dpt. Chemistry : project responsible in PPM2 (materials), FP4-BriteEuram, NEDO (Japan), Swiss Gas Union (CH, oxygen membranes).
1998-2000 : Masters in Energy Technology, EPFL.
2000 : Cofounder of HTceramix SA (EPFL spin-off), now based in Yverdon (14 employees). Taken over by SOLIDpower in 2007, now 250 employees with 70 MCHF raised.
2000 : 1st Assistant and lecturer at LENI (STI-IGM) : fuel cell group responsible, projects on biogas (Federal Energy Office), woodgas (CCEM), fuel cell stacking (CTI, FP6, FNS), ceramic separation membranes (COST, FNS), microtubes (STI Seed), stability/lifetime/reliability in fuel cells (Electricité de France, swisselectric research). Currently 4 Ph D theses ongoing, 14 theses concluded, of which 5 colateral with SB and IMX. M.E.R. since Nov 2008.
Total funding raised so far >18 MCHF (50% as main applicant; 30% outside CH; 20% industry).
Scientific output : >135 peer-reviewed publications, >120 conference papers, 40 invited presentations (8 keynotes), >70 granted proposals.
Fluent in 5 languages (Dutch, French, German ( Swiss-german), English, Spanish).
Roland LogéRoland Logé is an associate professor at EPFL, with a primary affiliation to the Materials Institute, and a secondary affiliation to the Microengineering Institute.
After graduating in 1994 at UCL (Belgium) in Materials Engineering, he earned a Master of Science in Mechanics in 1995, at UCSB Santa Barbara (USA). He received his PhD at Mines Paristech-CEMEF (France) in 1999, where he specialized in metal forming and associated microstructure evolutions. After a postdoc at Cornell University (USA) between 1999 and 2001, he entered CNRS in France.
In 2008, he was awarded the ALCAN prize from the French Academy of Sciences, together with Yvan Chastel.
In 2009 he became head of the Metallurgy-Structure-Rheology research group at CEMEF.
In 2011, he launched a “Groupement de Recherche” (GDR), funded by CNRS, networking most of the researchers in France involved in recrystallization and grain growth.
In 2013, he became Research Director at CNRS.
In March 2014 he joined EPFL as the head of the Laboratory of Thermomechanical Metallurgy.
Jean-François MolinariProfessor J.F. Molinari is the director of the Computational Solid Mechanics Laboratory (http://lsms.epfl.ch) at EPFL, Switzerland. He holds an appointment in the Civil Engineering institute, which he directed from 2013 to 2017, and a joint appointment in the Materials Science institute. He started his tenure at EPFL in 2007, and was promoted to Full Professor in 2012. He is currently an elected member of the Research Council of the Swiss National Science Foundation in Division 2 (Mathematics, Natural and Engineering Sciences), and co editor in chief of the journal Mechanics of Materials. J.F. Molinari graduated from Caltech, USA, in 2001, with a M.S. and Ph.D. in Aeronautics. He held professorships in several countries besides Switzerland, including the United States with a position in Mechanical Engineering at the Johns Hopkins University (2000-2006), and France at Ecole Normale Supérieure Cachan in Mechanics (2005-2007), as well as a Teaching Associate position at the Ecole Polytechnique de Paris (2006-2009). The work conducted by Prof. Molinari and his collaborators takes place at the frontier between traditional disciplines and covers several length scales from atomistic to macroscopic scales. Over the years, Professor Molinari and his group have been developing novel multiscale approaches for a seamless coupling across scales. The activities of the laboratory span the domains of damage mechanics of materials and structures, nano- and microstructural mechanical properties, and tribology. Pierre-Etienne BourbanBackground 1990 Ingénieur en science des matériaux 1993 PhD in materials science Activities 1993-1994 Research at the Center for Composite Materials, University of Delaware, USA (ccm.udel.edu), SNSF grant Since 1994 Research and teaching at EPFL, Composites, (LTC, LPAC) 1995-1999 Coordination Swiss Priority Program on Materials research: 2.2: Composites Since 1998 Biocomposites 2004-2009 Direction of the EPFL Transdisciplinary programme in Sport and Rehabilitation 2005-2008 Member of the EPFL Vice-Presidency for Innovation and Valorisation and direction a.i.EPFL-LTC Since 2016 Direction Discovery Learning Labs Materials/Bioengineering and Engineering
Heinrich HofmannOriginaire de Mellingen (AG), Heinrich Hofmann est né en 1953. Après des études d'ingénieur en soudures (Ing. grad.) à Duisburg (D), et d'ingénieur en science des matériaux à la Technische Hochschule de Berlin, il obtient le titre de docteur ingénieur en 1983 pour une thèse dans le domaine des matériaux.De 1983 à 1985, il travaille comme assistant scientifique au Laboratoire de Technologie des Poudres de l'Institut Max Planck pour la science des matériaux à Stuttgart. En 1985 il entre au Centre de Recherche et Développement d'Alusuisse-Lonza à Neuhausen-am-Rheinfall, en tant qu'ingénieur consacré à la recherche dans l'étude et le développement des procédés de synthèse des poudres céramiques.En 1993 il entre à l'EPFL en tant que professeur extraordinaire et directeur du Laboratoire de technologie des poudres du Départmeent des matériaux. Son enseignement porte sur les céramiques I (procédés) et les phénomènes de transfert. Son domaine de recherche couvre la synthèse des poudres minérales, leur caractérisation et la modification des surfaces, ainsi que la mise en forme et le frittage. Ses recherches incluent aussi les matériaux nanostructurés (composites semi-conducteurs et polymères) et la métallurgie des poudres. Hofmann Heinrich, Prof. Dr.-Ing. got his PhD in Material Science with a thesis prepared at the Powder Metallurgy Laboratory at the Max Planck Institute in Stuttgart. In 1985 he joins the R&D center of Alusuisse-Lonza Services AG, at Neuhausen-am-Rheinfall. In 1993 he joins the Swiss Federal Institute of Technology as Professor and Director of the Powder Technology Laboratory at the Department of Materials science and engineering. His research area includes the synthesis of nanostructured materials based on nanoparticles and the modification of surfaces with nanoparticles using colloidal methods. The fields of application of such materials are medical and biological, (drug delivery, hyperthermia, cell separation, biosensors), electronics and sensors.
