Engineering
Learn the fundamentals of microfabrication and nanofabrication by using the most effective techniques in a cleanroom environment.

Course Details

Language English
Duration 7 week
Effort 4 hour/week
Description

Microfabrication and nanofabrication are the basis of manufacturing for nearly all modern miniaturized systems that are ubiquitously used in our daily life. Examples include; computer chips and integrated sensors for monitoring our environment, cars, mobile phones, medical devices and more.

Micro- and nanofabrication can be taught to students and professionals by textbooks and ex-cathedra lectures, but the real learning comes from seeing the manufacturing steps as they happen.

In this engineering course, we will go a step beyond classroom teaching to not only explain the basics of each fabrication step but also show you how it’s done through video sequences and zooming into the equipment.

What you will learn


  • How to select the correct fabrication process for a specific micro-device or microsystem

  • Establish the workflow for the cleanroom processes

  • Identify how physical and chemical phenomena govern miniaturized systems for various applications

  • Resource planning for a given microsystem fabrication

Prerequisites

Basics in Physics and Chemistry

Plan

Week 1: MEMS and cleanroom introduction
This module introduces the basics of electromechanical systems (MEMS) and cleanroom fabrication. 

Week 2: Chemical vapor deposition (CVD)
This module on chemical vapor deposition or CVD describes in detail basic principles of CVD and will show you the cleanroom infrastructure that is used to run a CVD process. 

Week 3: Physical vapor deposition (PVD)
This module on physical vapor deposition describes in details the two main PVD methods; thermal evaporation and sputtering. 

Week 4: Lithography
This module on lithography describes in details the two main resist patterning methods: optical and electron beam lithography. 

Week 5: Dry etching
This module on dry etching describes etching in a gas environment. We will introduce etching directionality and anisotropy and give a few simple rules for choosing dry etching processes for specific materials in a plasma reactor and provide theoretical concepts that characterize a plasma in a dry etching equipment. 

Week 6: Wet etching
This module on wet etching describes etching in a liquid environment. We will introduce anisotropic wet etching of silicon substrates, where certain lattice planes are etched and others not, isotropic etching of silicon, and finally thin membrane microfabrication techniques using wet etching. 

Week 7: Inspection and metrology
This module describes methods of inspection and metrology based on four technique categories: optical, mechanical, charged beam and electrical.

Course instructors

Juergen Brugger

Juergen is Professor in Microengineering and Materials Science at the School of Engineering at EPFL. He received his Ph.D. from University of Neuchatel, Switzerland. Before joining EPFL he had research assignments at Hitachi Research in Tokyo, IBM Researc…

Martin Gijs

Martin is Professor of Microsystems at the School of Engineering at EPFL. He received his Ph.D. in Physics from the University of Leuven, Belgium in 1986. After his Ph.D. and before joining EPFL in 1997, he was a researcher at the Philips Research Laborat…

École polytechnique fédérale de Lausanne

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