4020175074 Discrete Quantum Optics
Digital- & Präsenz-basierter Kurs
- classroom language
- DE
- aims
- Upon completion of the course, students will be able to analyze optical processes taking place in integrated photonic devices in a quantum mechanical framework. The students will be familiar with the main quantum mechanical concepts that will allow them to pursue more advanced topics in quantum optics, semiconductor and solid-state physics, and modern optoelectronic and nanophotonic devices.
- requirements
- The material of the Bachelor of Physics, especially Electrodynamics, Optics, and Basic Quantum Physics
- structure / topics / contents
- - Review of Quantum Mechanics and 1D Problems with
focus on numerics
- Operator Algebra and Quantization of the
Electromagnetic field
- Fundamental Concepts and Devices of Discrete
Quantum Optics
- Propagation of Single Photons and Nonclassical
Light in integrated multiport Structures
- assigned modules
-
P25.4.b
P35.1
P35.3
- amount, credit points; Exam / major course assessment
- 4 SWS, 6 SP/ECTS (Arbeitsanteil im Modul für diese Lehrveranstaltung, nicht verbindlich)
Successful participation in the exercises and oral or written exam.
- contact
- Dr. Armando Perez-Leija (Max-Born-Institut, Haus A, Raum 2.09, Tel.: 6392-1213, armando.perez@mbi-berlin.de )
- literature
-
John David Jackson. Mathematics for Quantum Mechanics. Dover (1962)
Cristopher Gerry and Peter L. Knight. Introductory Quantum Optics. Cambridge University (2005)
Rodney Loudon. The Quantum Theory of Light. Oxford University Press (2000)
Markus Graefe et al.. Integrated Photonic Quantum Random Walks. J. of Optics, Topical Review, in press (2016)
Thomas Meany et al.. Laser written Circuits for Quantum Photonics. Laser & Photonics Reviews 9(4), 363-384 (2015)
- quod vide:
- http://www.physik.hu-berlin.de/top/teaching