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Diamond Nanophotonics
Aharonovich, Igor ; Neu, Elke
Advanced optical materials, 2014-10, Vol.2 (10), p.911-928
Weinheim: Wiley Subscription Services, Inc
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Título:
Diamond Nanophotonics
Autor:
Aharonovich, Igor
;
Neu, Elke
Assuntos:
Arrays
;
color centers
;
Cryogenic temperature
;
Diamonds
;
Electric fields
;
Emitters
;
nanophotonics
;
Nanostructure
;
NV centers
;
Optics
;
photonic cavities
;
photonic crystals
;
Photons
;
Semiconductors
;
SiV centers
É parte de:
Advanced optical materials, 2014-10, Vol.2 (10), p.911-928
Notas:
ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
Descrição:
The burgeoning field of nanophotonics has grown to be a major research area, primarily because of the ability to control and manipulate single quantum systems (emitters) and single photons on demand. For many years, studying nanophotonic phenomena was limited to traditional semiconductors (including silicon and GaAs) and experiments were carried out predominantly at cryogenic temperatures. In the last decade, however, diamond has emerged as a new contender to study photonic phenomena at the nanoscale. Offering a plethora of quantum emitters that are optically active at room temperature and ambient conditions, diamond has been exploited to demonstrate super‐resolution microscopy and realize entanglement, Purcell enhancement, and other quantum and classical nanophotonic effects. Elucidating the importance of diamond as a material, this progress report highlights the recent achievements in the field of diamond nanophotonics, and conveys a roadmap for future experiments and technological advancements. This progress report summarizes the recent advances in the field of diamond nanophotonics. It describes various single photon emitters and the fabrication of optical resonators, and it highlights the recent applications and quantum optics experiments carried out with diamond. The table of contents figure shows a nanodiamond array, superimposed with a finite‐difference time‐domain simulation of an electric field within a microdisk.
Editor:
Weinheim: Wiley Subscription Services, Inc
Idioma:
Inglês
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