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New Materials Session – Part I
Date: 19 October, Messe Dresden
Room: TechARENA, Hall 1 (free for all visitors)
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Session on the SEMI TechARENA are free and do not require pre-registration. Seating is limited, please arrive early.
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SESSION
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Session mentors: Didier Louis, Tom Beens, Ivo Raaijmakers
Session chair: Didier Louis, Tom Beens, Ivo Raaijmakers
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10:05
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SEMI overview and Standards Update
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10:15
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KEYNOTE: “RF and Optoelectronic System Applications of Compound Semiconductors”
Jean Chazelas, Director for R&T cooperation at the technical directorate of the Defence Mission Systems Division, Thales
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10:40
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“III-V Enabling New Compound Semiconductor Applications”
Fabrice Letertre, VP Corporate R&D, Soitec
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11:00
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“Materials and Device Solutions Beyond Moore”
Thomas Mikolajick, Director, Namlab
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11:20
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“Highly Efficient Organic Devices”
Karl Leo, Professor Institut für Angewandte Photophysik, Technical University Dresden; Director, Fraunhofer-Institute for Photonic Microsystems
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11.40
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“Materials for Thin Film Batteries”
Frédéric Fontaine, Technology & Application Manager, Umicore Thin Film Products
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12:00
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“Novel Materials and Processes Enabling Low-Power Autonomous Sensor Solutions”
Sywert H. Brongersma, Holst Centre/IMEC
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EXHIBITOR PRESENTATIONS
12:30
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"Innovative Process Equipment and Technologies for special Coatings in Microelectronics"
Hagen Bartzsch, Group Manager Static Deposition, Peter Frach, Head of Department Precision Coating, Fraunhofer Institute for Electron Beam and Plasma Technology FEP
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12:45
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"X-Ray Orientation Determination of Single- and Multi-Crystals"
Hans Berger, Senior Scientist, EFG GmbH
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About the presentations:
Materials and device solutions beyond Moore
Abstract:
With minimum feature sizes approaching 20nm, the physical and economical limits of CMOS devices will likely be reached in the next decade. To further increase the complexity and performance of electronic systems, new approaches have to be taken. Rather than relying on smaller and smaller physical size, the complexity has to be increased by radically changing the architecture of devices and systems. Two approaches that may help to overcome some of the limitations of today’s CMOS will be discussed. silicon nanowires offer new device configurations that can achieve reconfigurability of logic gates, while Memristors have the potential to remove the separation between memory and logic devices. For both silicon nanowires and Memristors material and device results will be presented and there potential to achieve complexity and performance beyond the physical limitations of Moore’s law will be discussed.
Biography
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Thomas Mikolajick, Director, Namlab
Career:
1990 – 1995 Scientific co-worker at University Erlangen Nuremberg1995 – 1996 Group leader Device and integration at FhG-IIS-, Erlangen
1996 – 1999 Process Engineer at Siemens Semiconductor Regensburg
1999 - 2000 Integration Manager “Ferroelectric Memories” at Infineon Munich
2000 - 2003 Project Leader “New Memory Technologies” at Infineon Technologies Munich
2003 - 2006 Project Leader Flash Predevelopment at Infieneon Dresden;
Principal Flash Technology since 2005
2006 - 2009 Head of Institute for Electronic- and Sensor Materials at TU Bergakademie Freiberg
2009 – present Head of Chair for Nanoelectronic Materials and Scientific Director of NamLab GmbH at TUD
Selected other Positions:
2005- present Head of DGM working group “materials for nonvolatile memories” http://www.leb.eei.uni-erlangen.de/DGM-AK
2006 - present Reviewer for: BMBF, DFG, EC and others
2009 - present Member of the Commission Microelectronics and Nanoelectronics of the state of Saxony (KOMINAS)
2009 – present Senior member of IEEE
2010 - present Coordinator of the Cool Silicon Cluster
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Highly Efficient Organic Devices
Abstract
Biography
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Karl Leo, Professor Institut für Angewandte Photophysik, Technical University Dresden; Director, Fraunhofer-Institute for Photonic Microsystems
Karl Leo obtained the Diplomphysiker degree from the University of Freiburg in 1985, working with Adolf Goetzberger at the Fraunhofer-Institut für Solare Energiesysteme. In 1988, he obtained the PhD degree from the University of Stuttgart for a PhD thesis performed at the Max-Planck-Institut für Festkörperforschung in Stuttgart under supervision of Hans Queisser. From 1989 to 1991, he was postdoc at AT&T Bell Laboratories in Holmdel, NJ, U.S.A. From 1991 to 1993, he was with the Rheinisch-Westfälische Technische Hochschule (RWTH) in Aachen, Germany. Since 1993, he is full professor of optoelectronics at the Technische Universität Dresden; since 2002, he is also at the Fraunhofer-Institute for Photonic Microsystems, presently as director. His main current interests are novel semiconductor systems like semiconducting organic thin films; with special emphasis to understand growth, basic device principles and the optical response. Recently, he has also worked on device development, such as highly efficient organic LED and solar cells. His work was recognized by the following awards: Otto-Hahn-Medaille (1989), Bennigsen-Förder-Preis (1991), Leibniz-Award (2002), and award of the Berlin-Brandenburg Academy (2002). He was involved in the founding of several companies including Novaled AG and Heliatek GmbH.
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Materials for Thin Film Batteries
Abstract
Energy harvesting is the process by which energy is derived from external sources, captured and stored. Some examples of external energy sources are solar, thermal, wind energy and kinetic energy or salinity gradients. In many cases the external sources are energy waste, which takes place at localized, difficult to access areas. Consequently, energy harvesting devices and in particular storage devices should be among others small and autonomous. One candidate for energy storage is the thin film battery. Small, thin film devices are devices, which typically can be fabricated by micro-electronics processes. The presentation will describe a state of the art thin film Li battery and its applications. It will discuss some aspects related to battery performance. The presentation will also show the materials needed, with a focus on the materials LiCoO2, Li3PO4 and Lithium.
Biography
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Frédéric Fontaine, Technology & Application Manager, Umicore Thin Film Products
Frédéric Fontaine obtained his PhD from the University Joseph Fourier in Grenoble in 1994. He has held several academic positions in Israel and Germany in the field of CVD/PVD and Ion Implantation. In 2000 he joined Gühring OhG as Project Manager and later as Deputy Director R&D to develop deposition equipment and hard coatings for wear protection. In 2005 he moved to Unaxis/Oerlikon Balzers Coating as Project Manager R&D. He joined Umicore Thin Film Products in 2008 as Product Development Manager and later as Technology and Application Manager. He has technical responsibilities for the sputtering and evaporation materials for the business line Electronics
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Novel Materials and Processes Enabling Low-Power Autonomous Sensor Solutions
Abstract
Biography
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Sywert H. Brongersma, Holst Centre/IMEC
Dr.Ir. Sywert H. Brongersma, born in Leiden (The Netherlands) on August 8 1967, studied applied Physics at the Technical University of Eindhoven. He graduated in 1991 on thin film deposition using laser ablation at the Philips NatLab in Eindhoven and obtained his Ph.D. at the Free University of Amsterdam in the field of superconductivity.
After a postdoc at the University of Western Ontario (Canada) he joined IMEC's Advanced Silicon Processing division in 1998. Here, he became a principal scientist for both the Cu/Low-k back-end-of-line integration and the Post-CMOS nano-technology affiliation programs. In November 2006, he transferred to IMEC's new site in Eindhoven that is part of the Holst Centre. At present, he is principal researcher for the wireless autonomous transducer solutions program and managing the sensors & actuators activity
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