Ultralow threshold on-chip microcavity nanocrystal quantum dot lasers

Bumki Min; Sungjee Kim; Koichi Okamoto; Lan Yang; Axel Scherer; Harry Atwater; Kerry Vahala

doi:10.1063/1.2387966

Ultralow threshold on-chip microcavity nanocrystal quantum dot lasers

Bumki Min, Sungjee Kim, Koichi Okamoto, Lan Yang, Axel Scherer, Harry Atwater, Kerry Vahala

Research output: Contribution to journal › Article › peer-review

92 Citations (Scopus)

Abstract

Chemically synthesized nanocrystal, CdSeZnS (core/shell), quantum dots are coated on the surface of an ultrahigh- Q toroidal microcavity and the lasing is observed at room and liquid nitrogen temperature by pulsed excitation of quantum dots, either through tapered fiber or free space. Use of a tapered fiber coupling substantially lowered the threshold energy when compared with the case of free space excitation. The reason for the threshold reduction is attributed to the efficient delivery of pump pulses to the active gain region of the toroidal microcavity. Further threshold reduction was possible by quantum dot surface-coverage control. By decreasing the quantum dot numbers on the surface of the cavity, the threshold energy is further decreased down to 9.9 fJ.

Original language	English
Article number	191124
Journal	Applied Physics Letters
Volume	89
Issue number	19
DOIs	https://doi.org/10.1063/1.2387966
Publication status	Published - 2006
Externally published	Yes

All Science Journal Classification (ASJC) codes

Physics and Astronomy (miscellaneous)

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10.1063/1.2387966

Cite this

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title = "Ultralow threshold on-chip microcavity nanocrystal quantum dot lasers",

abstract = "Chemically synthesized nanocrystal, CdSeZnS (core/shell), quantum dots are coated on the surface of an ultrahigh- Q toroidal microcavity and the lasing is observed at room and liquid nitrogen temperature by pulsed excitation of quantum dots, either through tapered fiber or free space. Use of a tapered fiber coupling substantially lowered the threshold energy when compared with the case of free space excitation. The reason for the threshold reduction is attributed to the efficient delivery of pump pulses to the active gain region of the toroidal microcavity. Further threshold reduction was possible by quantum dot surface-coverage control. By decreasing the quantum dot numbers on the surface of the cavity, the threshold energy is further decreased down to 9.9 fJ.",

author = "Bumki Min and Sungjee Kim and Koichi Okamoto and Lan Yang and Axel Scherer and Harry Atwater and Kerry Vahala",

year = "2006",

doi = "10.1063/1.2387966",

language = "English",

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T1 - Ultralow threshold on-chip microcavity nanocrystal quantum dot lasers

AU - Min, Bumki

AU - Kim, Sungjee

AU - Okamoto, Koichi

AU - Yang, Lan

AU - Scherer, Axel

AU - Atwater, Harry

AU - Vahala, Kerry

PY - 2006

Y1 - 2006

N2 - Chemically synthesized nanocrystal, CdSeZnS (core/shell), quantum dots are coated on the surface of an ultrahigh- Q toroidal microcavity and the lasing is observed at room and liquid nitrogen temperature by pulsed excitation of quantum dots, either through tapered fiber or free space. Use of a tapered fiber coupling substantially lowered the threshold energy when compared with the case of free space excitation. The reason for the threshold reduction is attributed to the efficient delivery of pump pulses to the active gain region of the toroidal microcavity. Further threshold reduction was possible by quantum dot surface-coverage control. By decreasing the quantum dot numbers on the surface of the cavity, the threshold energy is further decreased down to 9.9 fJ.

AB - Chemically synthesized nanocrystal, CdSeZnS (core/shell), quantum dots are coated on the surface of an ultrahigh- Q toroidal microcavity and the lasing is observed at room and liquid nitrogen temperature by pulsed excitation of quantum dots, either through tapered fiber or free space. Use of a tapered fiber coupling substantially lowered the threshold energy when compared with the case of free space excitation. The reason for the threshold reduction is attributed to the efficient delivery of pump pulses to the active gain region of the toroidal microcavity. Further threshold reduction was possible by quantum dot surface-coverage control. By decreasing the quantum dot numbers on the surface of the cavity, the threshold energy is further decreased down to 9.9 fJ.

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Ultralow threshold on-chip microcavity nanocrystal quantum dot lasers

Abstract

All Science Journal Classification (ASJC) codes

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