260132 VU Qubits, Spins and Quantum Sensors (2020S)
Continuous assessment of course work
Labels
Registration/Deregistration
Note: The time of your registration within the registration period has no effect on the allocation of places (no first come, first served).
- Registration is open from Mo 03.02.2020 08:00 to Mo 24.02.2020 07:00
- Deregistration possible until Th 30.04.2020 23:59
Details
max. 15 participants
Language: English
Lecturers
Classes (iCal) - next class is marked with N
- Wednesday 11.03. 16:00 - 18:15 Seminarraum Physik Sensengasse 8 EG
- Wednesday 18.03. 16:00 - 18:15 Seminarraum Physik Sensengasse 8 EG
- Wednesday 25.03. 16:00 - 18:15 Seminarraum Physik Sensengasse 8 EG
- Wednesday 01.04. 16:00 - 18:15 Seminarraum Physik Sensengasse 8 EG
- Wednesday 22.04. 16:00 - 18:15 Seminarraum Physik Sensengasse 8 EG
- Wednesday 29.04. 16:00 - 18:15 Seminarraum Physik Sensengasse 8 EG
- Wednesday 06.05. 16:00 - 18:15 Seminarraum Physik Sensengasse 8 EG
- Wednesday 13.05. 16:00 - 18:15 Seminarraum Physik Sensengasse 8 EG
- Wednesday 20.05. 16:00 - 18:15 Seminarraum Physik Sensengasse 8 EG
- Wednesday 27.05. 16:00 - 18:15 Seminarraum Physik Sensengasse 8 EG
- Wednesday 03.06. 16:00 - 18:15 Seminarraum Physik Sensengasse 8 EG
- Wednesday 10.06. 16:00 - 18:15 Seminarraum Physik Sensengasse 8 EG
- Wednesday 17.06. 16:00 - 18:15 Seminarraum Physik Sensengasse 8 EG
- Wednesday 24.06. 16:00 - 18:15 Seminarraum Physik Sensengasse 8 EG
Information
Aims, contents and method of the course
Assessment and permitted materials
Structure:
The lecture will be accompanied by elements of active participation by the students, including:
4 home exercise sheets
2 tests
2 presentations of a scientific paper by each student
1 laboratory-based assignment (e.g. design of a spin entanglement sequence)The laboratory-based assignment will include a tour of the solid-state spin quantum control experiments at the Faculty of Physics.
The lecture will be accompanied by elements of active participation by the students, including:
4 home exercise sheets
2 tests
2 presentations of a scientific paper by each student
1 laboratory-based assignment (e.g. design of a spin entanglement sequence)The laboratory-based assignment will include a tour of the solid-state spin quantum control experiments at the Faculty of Physics.
Minimum requirements and assessment criteria
Examination topics
Reading list
Association in the course directory
M-VAF A 2, M-VAF B, MaG 17, MaG 18, MaV 5, UF MA PHYS 01a, UF MA PHYS 01b
Last modified: Mo 07.09.2020 15:21
The lecture will comprise the concept of a qubit, some of its physical implementations and the core applications of such systems. The description of applications will include an overview of quantum computation, quantum communication, and quantum sensing.
A particular focus of the description will be placed on electronic and nuclear spins in semiconductors such as diamond, silicon, and silicon carbide. This focus will allow to underline the connection between quantum technology and “classical” nuclear magnetic resonance as well as electron spin resonance methods.
The course will outline the astounding technological and conceptual progress of the field in the last decades, examples of current research directions, and existing commercial pursuits.