Physics Department, TUM | Course 0000000689 in SS 2019

General Data

Course Type

lecture

Semester Weekly Hours

2 SWS

Organisational Unit

Experimental Semiconductor Physics

Lecturers

Martin Brandt

Dates

Thu, 14:00–16:00, ZNN 0.001

iCalendar

	Date and Time	Room and Remark
	Thu, 2019-04-25, 14:00–16:00	Am Coulombwall 4a
	Thu, 2019-05-02, 14:00–16:00	Am Coulombwall 4a
	Thu, 2019-05-09, 14:00–16:00	Am Coulombwall 4a
	Thu, 2019-05-23, 14:00–16:00	Am Coulombwall 4a
	Thu, 2019-06-06, 14:00–16:00	Am Coulombwall 4a
	Thu, 2019-06-13, 14:00–16:00	Am Coulombwall 4a
	Thu, 2019-06-27, 14:00–16:00	Am Coulombwall 4a
	Thu, 2019-07-04, 14:00–16:00	Am Coulombwall 4a
	Thu, 2019-07-11, 14:00–16:00	Am Coulombwall 4a
	Thu, 2019-07-18, 14:00–16:00	Am Coulombwall 4a
	Thu, 2019-07-25, 14:00–16:00	Am Coulombwall 4a

Assignment to Modules

PH2171: Halbleiterelektronik und Photonische Bauteile / Semiconductor Electronic and Photonic Devices
This module is included in the following catalogs:
- Specific catalogue of special courses for condensed matter physics
- Specific catalogue of special courses for Applied and Engineering Physics
- Complementary catalogue of special courses for nuclear, particle, and astrophysics
- Complementary catalogue of special courses for Biophysics

Further Information

Courses are together with exams the building blocks for modules. Please keep in mind that information on the contents, learning outcomes and, especially examination conditions are given on the module level only – see section "Assignment to Modules" above.

additional remarks	For more than 50 years semiconductor devices for information technologies and photonics have evolved from laboratory curiosities to mainstream devices with relevance for all aspects of our modern life. The aim of this course is to provide MSc. students in the Applied Engineering and Condensed Matter Physics study programs with an in-depth understanding of the fundamental physics underlying the operation of key semiconductor electronic and photonic devices. The course will provide students with insights into new approaches, materials and current research themes and is divided into two parts that, respectively, focus specifically on electronic and photonic micro- and nano-devices: Part 1 – will start by reviewing the physics of semiconductor junctions and metal-semiconductor contacts before continuing to explore bipolar junction and heterostructure bipolar transistors (BJTs, HBTs). We will also discuss secondary effects that impact on static and high frequency transistor performance. After this, we will explore field effect devices such as the junction FET, metal-semiconductor and -oxide devices (MISFET / MOSFET) and the use of complementary metal oxide semiconductor (CMOS) technologies for CCDs and DRAM. We will also discuss current challenges faced by CMOS technologies and discuss new concepts that move beyond CMOS including carbon nanostructures, molecular electronics and quantum dot based electronic nano-devices. Part 2 – focus will shift to linear and non-linear photonic devices including light emitting diodes, semiconductor optical amplifiers (SOA), non-linear photonic devices and lasers. Here, we will explore different ways to tailor the electronic and photonic components of the laser structure to obtain single mode operation and discuss recent trends to downscale both the laser cavity and the gain-medium to realise new classes of nano-lasers with enhanced performance and high modulation bandwidths. We will then continue to explore devices based on linear and non-linear optical phenomena including electro-, magneto- and acousto-optic effects. Finally, the course will conclude with a discussion of semiconductor and superconductor based solar-cells and photodetectors that can detect single photons with near unity quantum efficiency.
Links	Course documents E-Learning course (e. g. Moodle) TUMonline entry

additional remarks

For more than 50 years semiconductor devices for information technologies and photonics have evolved from laboratory curiosities to mainstream devices with relevance for all aspects of our modern life. The aim of this course is to provide MSc. students in the Applied Engineering and Condensed Matter Physics study programs with an in-depth understanding of the fundamental physics underlying the operation of key semiconductor electronic and photonic devices. The course will provide students with insights into new approaches, materials and current research themes and is divided into two parts that, respectively, focus specifically on electronic and photonic micro- and nano-devices: Part 1 – will start by reviewing the physics of semiconductor junctions and metal-semiconductor contacts before continuing to explore bipolar junction and heterostructure bipolar transistors (BJTs, HBTs). We will also discuss secondary effects that impact on static and high frequency transistor performance. After this, we will explore field effect devices such as the junction FET, metal-semiconductor and -oxide devices (MISFET / MOSFET) and the use of complementary metal oxide semiconductor (CMOS) technologies for CCDs and DRAM. We will also discuss current challenges faced by CMOS technologies and discuss new concepts that move beyond CMOS including carbon nanostructures, molecular electronics and quantum dot based electronic nano-devices. Part 2 – focus will shift to linear and non-linear photonic devices including light emitting diodes, semiconductor optical amplifiers (SOA), non-linear photonic devices and lasers. Here, we will explore different ways to tailor the electronic and photonic components of the laser structure to obtain single mode operation and discuss recent trends to downscale both the laser cavity and the gain-medium to realise new classes of nano-lasers with enhanced performance and high modulation bandwidths. We will then continue to explore devices based on linear and non-linear optical phenomena including electro-, magneto- and acousto-optic effects. Finally, the course will conclude with a discussion of semiconductor and superconductor based solar-cells and photodetectors that can detect single photons with near unity quantum efficiency.

Links

Course documents
E-Learning course (e. g. Moodle)
TUMonline entry

Equivalent Courses (e. g. in other semesters)

Semester	Title	Lecturers	Dates
SS 2018	Semiconductor Electronic and Photonic Devices	Sharp, I.	Thu, 14:00–16:00, ZNN 0.001
SS 2017	Semiconductor Electronic and Photonic Devices	Brandt, M.	Thu, 10:00–12:00, PH HS3 Fri, 12:00–14:00, PH HS3
SS 2016	Semiconductor Electronic and Photonic Devices	Brandt, M.	Fri, 08:30–10:00, PH HS2
SS 2015	Semiconductor Electronic and Photonic Devices	Finley, J.	Tue, 08:30–10:00, ZNN 0.001
SS 2014	Semiconductor Electronic and Photonic Devices	Finley, J.	Wed, 09:00–12:00, ZNN 0.001 Thu, 13:00–14:30, ZNN 0.001

Semiconductor Electronic and Photonic Devices

Course 0000000689 in SS 2019

General Data

Assignment to Modules

Further Information

Equivalent Courses (e. g. in other semesters)