Physics Department, TUM | Course 0000004427 in WS 2022/3

General Data

Course Type

lecture

Semester Weekly Hours

2 SWS

Organisational Unit

Associate Professorship of Quantum Electronics and Computer Engineering (Prof. Müller)

Lecturers

Kai Müller

Dates

Thu, 15:00–16:30, EI-Gar 03.5901.022

iCalendar

	Date and Time	Room and Remark
	Thu, 2022-10-20, 15:00–16:30	Hans-Piloty-Straße 1
	Thu, 2022-10-27, 15:00–16:30	Hans-Piloty-Straße 1
	Thu, 2022-11-03, 15:00–16:30	Hans-Piloty-Straße 1
	Thu, 2022-11-10, 15:00–16:30	Hans-Piloty-Straße 1
	Thu, 2022-11-17, 15:00–16:30	Hans-Piloty-Straße 1
	Thu, 2022-11-24, 15:00–16:30	Hans-Piloty-Straße 1
	Thu, 2022-12-08, 15:00–16:30	Hans-Piloty-Straße 1
	Thu, 2022-12-15, 15:00–16:30	Hans-Piloty-Straße 1
	Thu, 2022-12-22, 15:00–16:30	Hans-Piloty-Straße 1
	Thu, 2023-01-12, 15:00–16:30	Hans-Piloty-Straße 1
	Thu, 2023-01-19, 15:00–16:30	Hans-Piloty-Straße 1
	Thu, 2023-01-26, 15:00–16:30	Hans-Piloty-Straße 1
	Thu, 2023-02-02, 15:00–16:30	Hans-Piloty-Straße 1
	Thu, 2023-02-09, 15:00–16:30	Hans-Piloty-Straße 1

Assignment to Modules

CIT4430005: Photonic Quantum Technologies / Photonic Quantum Technologies
This module is included in the following catalogs:
- Focus Area Experimental Quantum Science & Technology in M.Sc. Quantum Science & Technology
- Catalogue of non-physics elective courses
EI70750: Photonic Quantum Technologies / Photonic Quantum Technologies

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	Photons travel with the speed of light and in various media can travel large distance without significant absorption. Therefore, they play a unique role in quantum technologies. The semiconductor platform is ideally suited for the generation of quantum states of light using quantum emitters and optically active spin qubits as well as for routing photons and creating effective photon-photon-interactions. This lecture will cover the fundamentals of photonic quantum technologies and highlight key applications. Specific aspects are: - Fundamentals of quantum photonics - Examples of optically-active semiconductor qubits - Quantum communication - Photonic quantum computing
Links	E-Learning course (e. g. Moodle) TUMonline entry

additional remarks

Photons travel with the speed of light and in various media can travel large distance without significant absorption. Therefore, they play a unique role in quantum technologies. The semiconductor platform is ideally suited for the generation of quantum states of light using quantum emitters and optically active spin qubits as well as for routing photons and creating effective photon-photon-interactions. This lecture will cover the fundamentals of photonic quantum technologies and highlight key applications. Specific aspects are: - Fundamentals of quantum photonics - Examples of optically-active semiconductor qubits - Quantum communication - Photonic quantum computing

Links

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

Equivalent Courses (e. g. in other semesters)

Semester	Title	Lecturers	Dates
SS 2023	Photonic Quantum Technologies	Müller, K.	Thu, 15:00–16:30, EI-Gar 03.5901.022
SS 2022	Photonic Quantum Technologies	Müller, K.	Thu, 15:00–16:30, EI-Gar 03.5901.022
WS 2021/2	Photonic Quantum Technologies	Müller, K.	Thu, 15:00–16:30, ZNN 0.001
SS 2021	Photonic Quantum Technologies	Müller, K.	Thu, 15:00–16:30, virtuell
WS 2020/1	Photonic Quantum Technologies	Müller, K.	Thu, 15:00–16:30, virtuell
SS 2020	Photonic Quantum Technologies	Müller, K.	Thu, 15:00–16:30, virtuell
WS 2019/20	Photonic Quantum Technologies	Müller, K.	Thu, 13:00–14:30, N1135 and singular or moved dates
SS 2019	Photonic Quantum Technologies	Müller, K.

Photonic Quantum Technologies

Course 0000004427 in WS 2022/3

General Data

Assignment to Modules

Further Information

Equivalent Courses (e. g. in other semesters)