Optoelectronic Technologies R1a

Overview

Credits points: 6


Workload:
60 hours course attendance; 120 hours self-study


Semester: summer


Language: English


Module type: elective


Module usability: M.Sc. Electrical Communication Engineering, M.Sc. Elektrotechnik


Module duration: one semester


Required qualifications:
Basic knowledge on semiconductor devices (transistor, laser diode, LED, photo diode), material science and optics

Competences to be acquired

Knowledge in micromachining, devices, thin layer and clean room technologies


Methodology in specialized miniaturization schemes and integration of electronic and optoelectronic devices and systems


Knowledge of design, fabrication and use of nanoelectronic, (opto-)electronic and micromachined devices

Courses

Content

  • Introduction to modern fabrication processes, technology of fibers, wave guides, lasers
  • Crystal growth: semiconductor wafers, thin layer epitaxy
  • Lithography: optical, X-ray, electron-beam, ion-beam, EUVL, nano imprint
  • Plasma processing and vacuum technology
  • Deposition techniques: evaporation, sputtering, plasma assisted techniques
  • Dry and wet-chemical etching and clean room technology

Learning outcomes

  • Understanding the fundamentals in micromachining, micro-opto-electro-mechanical systems (MOEMS) and optical MOEMS
  • Understanding the fundamentals of semiconductor technology including specific processes, schemes and required instrumentation

Details

  • Lecturer: Hartmut Hillmer and team
  • Teaching method: lecture
  • SWS: 2
  • Credit points: 3
  • Examination: oral exam (30 minutes)
  • Course identifier: FB16-5267

Content

  • Fabrication technology of electronic devices (planar transistor, electronic integrated chips), optoelectronic devices (semiconductor lasers, gratings) and micro-optoelectro-mechanical systems (MOEMS)
  • Introduction to micromachining, microsystem techniques, miniaturization, packaging and nanotechnology
  • Reasons for miniaturization and integration, types of micromachining
  • Sensors and actuators
  • Large variety of MEMS and MOEMS examples: membranes, springs, resonator elements, cantilevers, valves, manipulation elements, gripping tools, light modulators, optical switches, beam splitters, projection displays, micro optical bench, data distribution, micromachined tunable filters and lasers
  • Displays: micromachined (micromirror) displays, laser display technology, vacuumelectronics
  • Lab tour in the clean room

Learning outcomes

  • Methodology, interdisciplinary aspects, future perspectives and market trends
  • Finding solutions using interdisciplinary analogies
  • Establishing synergies between engineering disciplines and natural sciences
  • Introduction to the 21st century as the “century of photonics and nano technology”

Details

  • Lecturer: Hartmut Hillmer and team
  • Teaching method: lecture
  • SWS: 2
  • Credit points: 3
  • Examination: oral exam (30 minutes)
  • Course identifier: FB16-8500