Evaluation of the electron density and temperature in a sliding discharge

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A sliding discharge using two electrodes on a dielectric layer (upper electrodes) and a third electrode on its reverse side, facing the upper inter-electrode gap (lower electrode) was generated in air at atmospheric pressure. Application of a high dc negative voltage to one of the upper electrodes a...

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Autores principales: Kelly, H., Sosa, R., Grondona, D., Marquez, A., Lago, V., Artana, G.
Formato: CONF
Materias:
Ac voltage
Atomic models
Dielectric layer
Electron densities
Electron number
First negative systems
Generation frequency
Homogeneous surfaces
Interelectrode gaps
Line emissions
Negative voltage
Optical emissions
Plasma sheet
Positive systems
Reverse side
Sliding discharges
Spectral band
Third electrode
Transit time
Atmospheric pressure
Electrodes
Electron temperature
Electrons
Plasma diagnostics
Plasma sheaths
Electric discharges
Acceso en línea:http://hdl.handle.net/20.500.12110/paper_02811847_vT131_n_p_Kelly
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Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
id todo:paper_02811847_vT131_n_p_Kelly
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spelling todo:paper_02811847_vT131_n_p_Kelly2023-10-03T15:17:11Z Evaluation of the electron density and temperature in a sliding discharge Kelly, H. Sosa, R. Grondona, D. Marquez, A. Lago, V. Artana, G. Ac voltage Atomic models Dielectric layer Electron densities Electron number First negative systems Generation frequency Homogeneous surfaces Interelectrode gaps Line emissions Negative voltage Optical emissions Plasma sheet Positive systems Reverse side Sliding discharges Spectral band Third electrode Transit time Atmospheric pressure Electrodes Electron temperature Electrons Plasma diagnostics Plasma sheaths Electric discharges A sliding discharge using two electrodes on a dielectric layer (upper electrodes) and a third electrode on its reverse side, facing the upper inter-electrode gap (lower electrode) was generated in air at atmospheric pressure. Application of a high dc negative voltage to one of the upper electrodes and to the lower electrode, and a high ac voltage to the other upper electrode generates a stable and homogeneous surface plasma (plasma sheet) in the upper electrode's gap. In this work, the plasma sheet optical emission of the spectral bands corresponding to the 0-0 transition of the second positive system of N 2(λ=337.1 nm) and the first negative system of N 2 +(λ=391.4 nm) has been measured and analysed. It was found that the plasma sheet consisted of a set of cathode-directed streamers. The streamer generation frequency and its transit time across the inter-electrode gap have been studied. On the basis of a reliable atomic model to interpret the line emission, the total electron number at the streamer head and the electron temperature have been derived. © 2008 The Royal Swedish Academy of Sciences. CONF info:eu-repo/semantics/openAccess http://creativecommons.org/licenses/by/2.5/ar http://hdl.handle.net/20.500.12110/paper_02811847_vT131_n_p_Kelly
institution Universidad de Buenos Aires
institution_str I-28
repository_str R-134
collection Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic Ac voltage
Atomic models
Dielectric layer
Electron densities
Electron number
First negative systems
Generation frequency
Homogeneous surfaces
Interelectrode gaps
Line emissions
Negative voltage
Optical emissions
Plasma sheet
Positive systems
Reverse side
Sliding discharges
Spectral band
Third electrode
Transit time
Atmospheric pressure
Electrodes
Electron temperature
Electrons
Plasma diagnostics
Plasma sheaths
Electric discharges
spellingShingle Ac voltage
Atomic models
Dielectric layer
Electron densities
Electron number
First negative systems
Generation frequency
Homogeneous surfaces
Interelectrode gaps
Line emissions
Negative voltage
Optical emissions
Plasma sheet
Positive systems
Reverse side
Sliding discharges
Spectral band
Third electrode
Transit time
Atmospheric pressure
Electrodes
Electron temperature
Electrons
Plasma diagnostics
Plasma sheaths
Electric discharges
Kelly, H.
Sosa, R.
Grondona, D.
Marquez, A.
Lago, V.
Artana, G.
Evaluation of the electron density and temperature in a sliding discharge
topic_facet Ac voltage
Atomic models
Dielectric layer
Electron densities
Electron number
First negative systems
Generation frequency
Homogeneous surfaces
Interelectrode gaps
Line emissions
Negative voltage
Optical emissions
Plasma sheet
Positive systems
Reverse side
Sliding discharges
Spectral band
Third electrode
Transit time
Atmospheric pressure
Electrodes
Electron temperature
Electrons
Plasma diagnostics
Plasma sheaths
Electric discharges
description A sliding discharge using two electrodes on a dielectric layer (upper electrodes) and a third electrode on its reverse side, facing the upper inter-electrode gap (lower electrode) was generated in air at atmospheric pressure. Application of a high dc negative voltage to one of the upper electrodes and to the lower electrode, and a high ac voltage to the other upper electrode generates a stable and homogeneous surface plasma (plasma sheet) in the upper electrode's gap. In this work, the plasma sheet optical emission of the spectral bands corresponding to the 0-0 transition of the second positive system of N 2(λ=337.1 nm) and the first negative system of N 2 +(λ=391.4 nm) has been measured and analysed. It was found that the plasma sheet consisted of a set of cathode-directed streamers. The streamer generation frequency and its transit time across the inter-electrode gap have been studied. On the basis of a reliable atomic model to interpret the line emission, the total electron number at the streamer head and the electron temperature have been derived. © 2008 The Royal Swedish Academy of Sciences.
format CONF
author Kelly, H.
Sosa, R.
Grondona, D.
Marquez, A.
Lago, V.
Artana, G.
author_facet Kelly, H.
Sosa, R.
Grondona, D.
Marquez, A.
Lago, V.
Artana, G.
author_sort Kelly, H.
title Evaluation of the electron density and temperature in a sliding discharge
title_short Evaluation of the electron density and temperature in a sliding discharge
title_full Evaluation of the electron density and temperature in a sliding discharge
title_fullStr Evaluation of the electron density and temperature in a sliding discharge
title_full_unstemmed Evaluation of the electron density and temperature in a sliding discharge
title_sort evaluation of the electron density and temperature in a sliding discharge
url http://hdl.handle.net/20.500.12110/paper_02811847_vT131_n_p_Kelly
work_keys_str_mv AT kellyh evaluationoftheelectrondensityandtemperatureinaslidingdischarge
AT sosar evaluationoftheelectrondensityandtemperatureinaslidingdischarge
AT grondonad evaluationoftheelectrondensityandtemperatureinaslidingdischarge
AT marqueza evaluationoftheelectrondensityandtemperatureinaslidingdischarge
AT lagov evaluationoftheelectrondensityandtemperatureinaslidingdischarge
AT artanag evaluationoftheelectrondensityandtemperatureinaslidingdischarge
_version_ 1807324655034302464

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