Origin of optical losses in gallium arsenide disk whispering gallery resonators

David Parrain; Christophe Baker; Guillaume Wang; Biswarup Guha; Eduardo Gil Santos; Aristide Lemaitre; Pascale Senellart; Giuseppe Leo; Sara Ducci; Ivan Favero

doi:10.1364/OE.23.019656

Origin of optical losses in gallium arsenide disk whispering gallery resonators

David Parrain
, Christophe Baker
, Guillaume Wang
, Biswarup Guha
, Eduardo Gil Santos
, Aristide Lemaitre
, Pascale Senellart
, Giuseppe Leo
, Sara Ducci
, Ivan Favero

Université de Paris
Centre de Nanosciences et de Nanotechnologies

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

Abstract

Whispering gallery modes in GaAs disk resonators reach half a million of optical quality factor. These high Qs remain still well below the ultimate design limit set by bending losses. Here we investigate the origin of residual optical dissipation in these devices. A Transmission Electron Microscope analysis is combined with an improved Volume Current Method to precisely quantify optical scattering losses by roughness and waviness of the structures, and gauge their importance relative to intrinsic material and radiation losses. The analysis also provides a qualitative description of the surface reconstruction layer, whose optical absorption is then revealed by comparing spectroscopy experiments in air and in different liquids. Other linear and nonlinear optical loss channels in the disks are evaluated likewise. Routes are given to further improve the performances of these miniature GaAs cavities.

Original language	English
Pages (from-to)	19656-19672
Number of pages	17
Journal	Optics Express
Volume	23
Issue number	15
DOIs	https://doi.org/10.1364/OE.23.019656
Publication status	Published - 27 Jul 2015
Externally published	Yes

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title = "Origin of optical losses in gallium arsenide disk whispering gallery resonators",

abstract = "Whispering gallery modes in GaAs disk resonators reach half a million of optical quality factor. These high Qs remain still well below the ultimate design limit set by bending losses. Here we investigate the origin of residual optical dissipation in these devices. A Transmission Electron Microscope analysis is combined with an improved Volume Current Method to precisely quantify optical scattering losses by roughness and waviness of the structures, and gauge their importance relative to intrinsic material and radiation losses. The analysis also provides a qualitative description of the surface reconstruction layer, whose optical absorption is then revealed by comparing spectroscopy experiments in air and in different liquids. Other linear and nonlinear optical loss channels in the disks are evaluated likewise. Routes are given to further improve the performances of these miniature GaAs cavities.",

author = "David Parrain and Christophe Baker and Guillaume Wang and Biswarup Guha and Santos, \{Eduardo Gil\} and Aristide Lemaitre and Pascale Senellart and Giuseppe Leo and Sara Ducci and Ivan Favero",

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AU - Parrain, David

AU - Baker, Christophe

AU - Wang, Guillaume

AU - Guha, Biswarup

AU - Santos, Eduardo Gil

AU - Lemaitre, Aristide

AU - Senellart, Pascale

AU - Leo, Giuseppe

AU - Ducci, Sara

AU - Favero, Ivan

PY - 2015/7/27

Y1 - 2015/7/27

N2 - Whispering gallery modes in GaAs disk resonators reach half a million of optical quality factor. These high Qs remain still well below the ultimate design limit set by bending losses. Here we investigate the origin of residual optical dissipation in these devices. A Transmission Electron Microscope analysis is combined with an improved Volume Current Method to precisely quantify optical scattering losses by roughness and waviness of the structures, and gauge their importance relative to intrinsic material and radiation losses. The analysis also provides a qualitative description of the surface reconstruction layer, whose optical absorption is then revealed by comparing spectroscopy experiments in air and in different liquids. Other linear and nonlinear optical loss channels in the disks are evaluated likewise. Routes are given to further improve the performances of these miniature GaAs cavities.

AB - Whispering gallery modes in GaAs disk resonators reach half a million of optical quality factor. These high Qs remain still well below the ultimate design limit set by bending losses. Here we investigate the origin of residual optical dissipation in these devices. A Transmission Electron Microscope analysis is combined with an improved Volume Current Method to precisely quantify optical scattering losses by roughness and waviness of the structures, and gauge their importance relative to intrinsic material and radiation losses. The analysis also provides a qualitative description of the surface reconstruction layer, whose optical absorption is then revealed by comparing spectroscopy experiments in air and in different liquids. Other linear and nonlinear optical loss channels in the disks are evaluated likewise. Routes are given to further improve the performances of these miniature GaAs cavities.

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DO - 10.1364/OE.23.019656

M3 - Article

AN - SCOPUS:84954510761

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VL - 23

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JO - Optics Express

JF - Optics Express

IS - 15

ER -

Origin of optical losses in gallium arsenide disk whispering gallery resonators

Abstract

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