Competition between sub-bandgap linear detection and degenerate two-photon absorption in gallium arsenide photodiodes

Benjamin Vest; Baptiste Fix; Julien Jaeck; Riad Haïdar

doi:10.1186/s41476-016-0022-8

Competition between sub-bandgap linear detection and degenerate two-photon absorption in gallium arsenide photodiodes

Benjamin Vest
, Baptiste Fix
, Julien Jaeck
, Riad Haïdar

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

Abstract

This letter is on the response of gallium arsenide p-i-n diodes to sub-bandgap photons (1.55 μm). We investigate the various regimes of sub-bandgap operation by using different light sources delivering pulses ranging from nanosecond to microsecond durations. We evidence two regimes : a regime of degenerate two-photon absorption, with a clear quadratic dependence with respect to the incident flux, and a sub-bandgap, temperature dependant linear regime, that drives photocurrent generation at lower power densities. Both processes are associated to a very low quantum efficiency, around 10–8. We then determine absorption coefficients as well as trap densities, thanks to a model involving a photo-assisted Shockley Read Hall effect.

Original language	English
Article number	26
Journal	Journal of the European Optical Society
Volume	12
Issue number	1
DOIs	https://doi.org/10.1186/s41476-016-0022-8
Publication status	Published - 1 Dec 2016
Externally published	Yes

Keywords

Defects
Detection
Gallium arsenide
Non-linear optics
Two-photon absorption

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10.1186/s41476-016-0022-8

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abstract = "This letter is on the response of gallium arsenide p-i-n diodes to sub-bandgap photons (1.55 μm). We investigate the various regimes of sub-bandgap operation by using different light sources delivering pulses ranging from nanosecond to microsecond durations. We evidence two regimes : a regime of degenerate two-photon absorption, with a clear quadratic dependence with respect to the incident flux, and a sub-bandgap, temperature dependant linear regime, that drives photocurrent generation at lower power densities. Both processes are associated to a very low quantum efficiency, around 10–8. We then determine absorption coefficients as well as trap densities, thanks to a model involving a photo-assisted Shockley Read Hall effect.",

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AU - Vest, Benjamin

AU - Fix, Baptiste

AU - Jaeck, Julien

AU - Haïdar, Riad

PY - 2016/12/1

Y1 - 2016/12/1

N2 - This letter is on the response of gallium arsenide p-i-n diodes to sub-bandgap photons (1.55 μm). We investigate the various regimes of sub-bandgap operation by using different light sources delivering pulses ranging from nanosecond to microsecond durations. We evidence two regimes : a regime of degenerate two-photon absorption, with a clear quadratic dependence with respect to the incident flux, and a sub-bandgap, temperature dependant linear regime, that drives photocurrent generation at lower power densities. Both processes are associated to a very low quantum efficiency, around 10–8. We then determine absorption coefficients as well as trap densities, thanks to a model involving a photo-assisted Shockley Read Hall effect.

AB - This letter is on the response of gallium arsenide p-i-n diodes to sub-bandgap photons (1.55 μm). We investigate the various regimes of sub-bandgap operation by using different light sources delivering pulses ranging from nanosecond to microsecond durations. We evidence two regimes : a regime of degenerate two-photon absorption, with a clear quadratic dependence with respect to the incident flux, and a sub-bandgap, temperature dependant linear regime, that drives photocurrent generation at lower power densities. Both processes are associated to a very low quantum efficiency, around 10–8. We then determine absorption coefficients as well as trap densities, thanks to a model involving a photo-assisted Shockley Read Hall effect.

KW - Defects

KW - Detection

KW - Gallium arsenide

KW - Non-linear optics

KW - Two-photon absorption

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DO - 10.1186/s41476-016-0022-8

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JO - Journal of the European Optical Society

JF - Journal of the European Optical Society

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ER -

Competition between sub-bandgap linear detection and degenerate two-photon absorption in gallium arsenide photodiodes

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Keywords

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