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Electrically driven quantum dot base...

Kantner, Markus.

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Electrically driven quantum dot based single-photon sources = modeling and simulation /

Record Type:	Electronic resources : Monograph/item
Title/Author:	Electrically driven quantum dot based single-photon sources/ by Markus Kantner.
Reminder of title:	modeling and simulation /
Author:	Kantner, Markus.
Published:	Cham :Springer International Publishing : : 2020.,
Description:	xvii, 180 p. :ill. (some col.), digital ;24 cm.
[NT 15003449]:	Introduction -- Semi-classical charge transport in semiconductor devices -- Numerical simulation of carrier transport at cryogenic temperatures -- Current injection into oxide-confined single-photon emitting diodes -- Hybrid modeling of electrically driven quantum light sources -- Hybrid simulation of an electrically driven single-photon source -- Summary and outlook -- Appendix.
Contained By:	Springer eBooks
Subject:	Quantum optics. -
Online resource:	https://doi.org/10.1007/978-3-030-39543-8
ISBN:	9783030395438

Electrically driven quantum dot based single-photon sources = modeling and simulation /
Kantner, Markus.

Electrically driven quantum dot based single-photon sourcesmodeling and simulation /[electronic resource] :by Markus Kantner. - Cham :Springer International Publishing :2020. - xvii, 180 p. :ill. (some col.), digital ;24 cm. - Springer theses,2190-5053. - Springer theses..

Introduction -- Semi-classical charge transport in semiconductor devices -- Numerical simulation of carrier transport at cryogenic temperatures -- Current injection into oxide-confined single-photon emitting diodes -- Hybrid modeling of electrically driven quantum light sources -- Hybrid simulation of an electrically driven single-photon source -- Summary and outlook -- Appendix.

Semiconductor quantum optics is on the verge of moving from the lab to real world applications. When stepping from basic research to new technologies, device engineers will need new simulation tools for the design and optimization of quantum light sources, which combine classical device physics with cavity quantum electrodynamics. This thesis aims to provide a holistic description of single-photon emitting diodes by bridging the gap between microscopic and macroscopic modeling approaches. The central result is a novel hybrid quantum-classical model system that self-consistently couples semi-classical carrier transport theory with open quantum many-body systems. This allows for a comprehensive description of quantum light emitting diodes on multiple scales: It enables the calculation of the quantum optical figures of merit together with the simulation of the spatially resolved current flow in complex, multi-dimensional semiconductor device geometries out of one box. The hybrid system is shown to be consistent with fundamental laws of (non-)equilibrium thermodynamics and is demonstrated by numerical simulations of realistic devices.

ISBN: 9783030395438

Standard No.: 10.1007/978-3-030-39543-8doiSubjects--Topical Terms:

525557
Quantum optics.

LC Class. No.: QC446.2 / .K368 2020

Dewey Class. No.: 535.15

Electrically driven quantum dot based single-photon sources = modeling and simulation /
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505 0 $a Introduction -- Semi-classical charge transport in semiconductor devices -- Numerical simulation of carrier transport at cryogenic temperatures -- Current injection into oxide-confined single-photon emitting diodes -- Hybrid modeling of electrically driven quantum light sources -- Hybrid simulation of an electrically driven single-photon source -- Summary and outlook -- Appendix.
520 $a Semiconductor quantum optics is on the verge of moving from the lab to real world applications. When stepping from basic research to new technologies, device engineers will need new simulation tools for the design and optimization of quantum light sources, which combine classical device physics with cavity quantum electrodynamics. This thesis aims to provide a holistic description of single-photon emitting diodes by bridging the gap between microscopic and macroscopic modeling approaches. The central result is a novel hybrid quantum-classical model system that self-consistently couples semi-classical carrier transport theory with open quantum many-body systems. This allows for a comprehensive description of quantum light emitting diodes on multiple scales: It enables the calculation of the quantum optical figures of merit together with the simulation of the spatially resolved current flow in complex, multi-dimensional semiconductor device geometries out of one box. The hybrid system is shown to be consistent with fundamental laws of (non-)equilibrium thermodynamics and is demonstrated by numerical simulations of realistic devices.
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