Physics Department, TUM | Course 0000001005 in SS 2019

General Data

Course Type

lecture

Semester Weekly Hours

3 SWS

Organisational Unit

Chair of Nano and Quantum Sensors (Prof. Weig)

Lecturers

Johannes Russer

Dates

Wed, 10:45–13:00, 1400

iCalendar

	Date and Time	Room and Remark
	Wed, 2019-04-24, 10:45–13:00	Arcisstr. 21
	Wed, 2019-05-15, 10:45–13:00	Arcisstr. 21
	Wed, 2019-05-22, 10:45–13:00	Arcisstr. 21
	Wed, 2019-05-29, 10:45–13:00	Arcisstr. 21
	Wed, 2019-06-05, 10:45–13:00	Arcisstr. 21
	Wed, 2019-06-12, 10:45–13:00	Arcisstr. 21
	Wed, 2019-06-19, 10:45–13:00	Arcisstr. 21
	Wed, 2019-06-26, 10:45–13:00	Arcisstr. 21
	Wed, 2019-07-03, 10:45–13:00	Arcisstr. 21
	Wed, 2019-07-10, 10:45–13:00	Arcisstr. 21
	Wed, 2019-07-17, 10:45–13:00	Arcisstr. 21
	Wed, 2019-07-24, 10:45–13:00	Arcisstr. 21

Assignment to Modules

EI7203: Quantum Nanoelectronics / Quantum Nanoelectronics

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	The influence of quantum mechanics on electronics, nanoelectronics and information theory, early quantum theory of radiation, Planck’s radiation law, the photoelectric effect, spontaneous and induced emission, quantum properties of matter, the matter wave, the Schrödinger equation, the observability of physical quantities, expectation values of observables, eigenfunctions and eigenvalues of operators, stationary states, particle in square well potential, the one-dimensional harmonic oscillator, the hydrogen Atom, atoms, molecules, solids, nanostructures, the Hilbert space representation of states and observables, Dirac vectors, dynamics of quantum systems, the Schrödinger Representation, the Heisenberg representation, the Interaction representation, algebraic treatment of the harmonic oscillator, quantum information theory, the Einstein Podolsky Rosen experiment, entangled states, the quantization of the electromagnetic field, quantum theory of electric circuits, coherent states, interaction of radiation and matter, emission and absorption of radiation, the natural line width of an atom, quantum statistics, the density operator, the coherent state and the Poisson distribution, signal and noise, the characteristic function, photon field coupled to a reservoir of a two-level atom, laser theory, superconductivity, the Josephson effect, quantization of the JC circuit, quantum computing, basic operations in quantum computing, the no-cloning theorem, quantum teleportation
Links	E-Learning course (e. g. Moodle) TUMonline entry

additional remarks

The influence of quantum mechanics on electronics, nanoelectronics and information theory, early quantum theory of radiation, Planck’s radiation law, the photoelectric effect, spontaneous and induced emission, quantum properties of matter, the matter wave, the Schrödinger equation, the observability of physical quantities, expectation values of observables, eigenfunctions and eigenvalues of operators, stationary states, particle in square well potential, the one-dimensional harmonic oscillator, the hydrogen Atom, atoms, molecules, solids, nanostructures, the Hilbert space representation of states and observables, Dirac vectors, dynamics of quantum systems, the Schrödinger Representation, the Heisenberg representation, the Interaction representation, algebraic treatment of the harmonic oscillator, quantum information theory, the Einstein Podolsky Rosen experiment, entangled states, the quantization of the electromagnetic field, quantum theory of electric circuits, coherent states, interaction of radiation and matter, emission and absorption of radiation, the natural line width of an atom, quantum statistics, the density operator, the coherent state and the Poisson distribution, signal and noise, the characteristic function, photon field coupled to a reservoir of a two-level atom, laser theory, superconductivity, the Josephson effect, quantization of the JC circuit, quantum computing, basic operations in quantum computing, the no-cloning theorem, quantum teleportation

Links

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

Equivalent Courses (e. g. in other semesters)

Semester	Title	Lecturers	Dates
SS 2020	Quantum Nanoelectronics	Russer, J.	Wed, 10:45–13:00, N1816
SS 2018	Quantum Nanoelectronics	Russer, J.	Wed, 10:45–13:00, 1400 and singular or moved dates
SS 2017	Quantum Nanoelectronics	Russer, J.	Wed, 10:45–13:00, 1400
SS 2016	Quantum Nanoelectronics	Russer, J.	Wed, 10:45–13:00, 3999 and singular or moved dates
SS 2015	Quantum Nanoelectronics	Lugli, P. Russer, J.	Wed, 11:30–13:45, 3999
SS 2014	Quantum Nanoelectronics	Lugli, P. Russer, J.	Wed, 11:30–13:45, 3999
SS 2013	Quantum Nanoelectronics	Lugli, P. Russer, J.
SS 2012	Quantum Nanoelectronics	Lugli, P. Russer, J.
SS 2011	Quantum Nanoelectronics	Russer, J. Responsible/Coordination: Lugli, P.

Quantum Nanoelectronics

Course 0000001005 in SS 2019

General Data

Assignment to Modules

Further Information

Equivalent Courses (e. g. in other semesters)