Jürgen Brugger
EPFL STI IMT LMIS1
BM 3107 (Bâtiment BM)
Station 17
1015 Lausanne
+41 21 693 65 73
Office: BM 3107
EPFL › STI › IEM › LMIS1
Site web: https://lmis1.epfl.ch/
Formation
PhD
| Physical-Electronics
1995 – 1995
Neuchatel
Dirigée par
Thesis advisor: Prof. N.F. de Rooij (IMT Universite de Neuchatel)
Diplome (M.Sc.)
| Electronique-Physique1990 – 1990 Neuchatel
Expériences professionnelles
Full Professor
Associate Professor
Assistant Professor
Research Program Coordinator "NanoLink"
Infoscience
Doctorant·es actuel·les
Shulang Shen, Tao Zhang, Pol Torres Vila, Qinglan Shan, Chenhao Wang, Chenxiang Zhang
A dirigé les thèses EPFL de
Mario Andres Chavarria Varon, Mohammadmahdi Kiaee, Zhiwei Yang, Mattia Marelli, Vahid Fakhfouri, Valentin Flauraud, Henry Shao-Chi Yu, Grégory Mermoud, Lorenz Hagelüken, Kristopher Pataky, Katrin Sidler Arnet, Enrica Montinaro, Thomas Walger, Jonas Gustav Henriksson, Johannes Steen, Yi-Chiang Sun, Shenqi Xie, Loïc Jacot-Descombes, Thomas Kiefer, Jonas Grossenbacher, Oscar Vazquez Mena, Sivashankar Krishnamoorthy, Roberto Russo, Samuel Tobias Howell, Ya Wang, Jongeon Park, Berke Erbas, Mona Julia Katharina Klein, Mirjana Banjevic, Matthieu Jean Michel Rüegg
Cours
MEMS sensors practicals
Objective of this practical is to apply in specific experimental settings the knowledge acquired in various MEMS related class
Advanced topics in micro- and nanomanufacturing: top-down meets bottom-up
This course introduces advanced fabrication methods enabling the manufacturing of novel micro- and nanosystems (NEMS/MEMS). Both top-down techniques (lithography, stenciling, scanning probes, additive techniques) and bottom-up approaches (self-assembly) are presented.
Microfabrication technologies
The student will learn process techniques and applications of modern micro- and nanofabrication technologies, as practiced in a standard clean room, with focus on silicon mainstream and microsystems technologies.
Selected topics in advanced manufacturing
Advanced additive manufacturing technologies
Advanced 3D forming techniques for high throughput and high resolution (nanometric) for large scale production. Digital manufacturing of functional layers, microsystems and smart systems.
Introduction to additive manufacturing
The state of the art in the domain of additive production processes (the part is built by material addition without use of a shape tool) will be presented. The main application/benefits/shortcomings of the common additive processes as well as technological and economical issues will be discussed.
MOOC: Micro and Nanofabrication (MEMS) - Spring
Microfabrication practicals
The goal of this course is to introduce students to the practical aspects of some basic micro-fabrication techniques.
Advanced microfabrication practicals
Nanotechnology
Soft Microsystems Processing and Devices
Amongst others, following topics will be covered during the course: - Soft Microsystems and Electronics - Electroactive polymers - Printed electronics and microsystems - Inkjet printing of polymers - Stretchable electronics - Mechanical reliability - Stencil lithography - Scanning Probe Lithography
MEMS practicals I
Objective of this practical is to apply in specific experimental settings the knowledge acquired in various MEMS related class