Gas discharge response to light: Dependence of linearity on space charge for optogalvanic and excited-state photoionization signals

N. S. Kopeika; T. Karcher; C. S. Ih

doi:10.1364/AO.18.003513

Gas discharge response to light: Dependence of linearity on space charge for optogalvanic and excited-state photoionization signals

N. S. Kopeika, T. Karcher, C. S. Ih

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

16 Scopus citations

Abstract

Experiments involving He-Cd and Ar laser beam interactions with an Ar discharge indicate that space charge effects generated by the incident light itself are the physical mechanism responsible for nonlinearity of response in discharge regions of excited atom concentration spatial gradients.This occurs with both excited atom photoionization and optogalvanic signals.Such optically generated space charges explain the role of electrode geometry in forming effective cross sections which have been used to describe mathematically the nonlinearity.The optogalvanic effect here is greater in Townsend than in glow discharges, particularly in the cathode fall.This is advantageous because of the extremely low noise and higher responsivities of Townsend discharges.

Original language	English
Pages (from-to)	3513-3516
Number of pages	4
Journal	Applied Optics
Volume	18
Issue number	20
DOIs	https://doi.org/10.1364/AO.18.003513
State	Published - 15 Oct 1979
Externally published	Yes

ASJC Scopus subject areas

Atomic and Molecular Physics, and Optics
Engineering (miscellaneous)
Electrical and Electronic Engineering

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10.1364/AO.18.003513

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abstract = "Experiments involving He-Cd and Ar laser beam interactions with an Ar discharge indicate that space charge effects generated by the incident light itself are the physical mechanism responsible for nonlinearity of response in discharge regions of excited atom concentration spatial gradients.This occurs with both excited atom photoionization and optogalvanic signals.Such optically generated space charges explain the role of electrode geometry in forming effective cross sections which have been used to describe mathematically the nonlinearity.The optogalvanic effect here is greater in Townsend than in glow discharges, particularly in the cathode fall.This is advantageous because of the extremely low noise and higher responsivities of Townsend discharges.",

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year = "1979",

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AU - Ih, C. S.

PY - 1979/10/15

Y1 - 1979/10/15

N2 - Experiments involving He-Cd and Ar laser beam interactions with an Ar discharge indicate that space charge effects generated by the incident light itself are the physical mechanism responsible for nonlinearity of response in discharge regions of excited atom concentration spatial gradients.This occurs with both excited atom photoionization and optogalvanic signals.Such optically generated space charges explain the role of electrode geometry in forming effective cross sections which have been used to describe mathematically the nonlinearity.The optogalvanic effect here is greater in Townsend than in glow discharges, particularly in the cathode fall.This is advantageous because of the extremely low noise and higher responsivities of Townsend discharges.

AB - Experiments involving He-Cd and Ar laser beam interactions with an Ar discharge indicate that space charge effects generated by the incident light itself are the physical mechanism responsible for nonlinearity of response in discharge regions of excited atom concentration spatial gradients.This occurs with both excited atom photoionization and optogalvanic signals.Such optically generated space charges explain the role of electrode geometry in forming effective cross sections which have been used to describe mathematically the nonlinearity.The optogalvanic effect here is greater in Townsend than in glow discharges, particularly in the cathode fall.This is advantageous because of the extremely low noise and higher responsivities of Townsend discharges.

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Gas discharge response to light: Dependence of linearity on space charge for optogalvanic and excited-state photoionization signals

Abstract

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