ROLE OF ELECTRON DISSOCIATIVE ATTACHMENT AND IMPACT DISSOCIATION OF HCL IN XECL LASERS.

E. T. Salesky; W. D. Kimura; F. Kannari

ROLE OF ELECTRON DISSOCIATIVE ATTACHMENT AND IMPACT DISSOCIATION OF HCL IN XECL LASERS.

E. T. Salesky, W. D. Kimura, F. Kannari

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Abstract

A computer model of electron-beam pumped XeCl laser mixtures has been developed that uses a time-dependent Boltzmann solution for the secondary electron distribution. The model has been improved by including HCl vibration levels for v greater than 2 and additional HCl chemistry. For the pump conditions of the electron density and HCl burnup measurements, the model predicts that the secondary electron distribution is significantly non-Maxwellian. It also supports the conclusion that the initial rapid increase of the electron density at the beginning of the pump pulse is due to the finite vibrational excitation time of HCl. The model and data also indicate that electron dissociative attachment by itself cannot adequately explain the increase in the electron density toward the end of the pulse.

Original language	English
Title of host publication	Unknown Host Publication Title
Publisher	Optical Soc of America
Number of pages	1
ISBN (Print)	0936659491
Publication status	Published - 1987 Jan 1
Externally published	Yes

ASJC Scopus subject areas

Engineering(all)

Cite this

@inproceedings{ed538bca4d0641f4acde2cf2298f68d6,

title = "ROLE OF ELECTRON DISSOCIATIVE ATTACHMENT AND IMPACT DISSOCIATION OF HCL IN XECL LASERS.",

abstract = "A computer model of electron-beam pumped XeCl laser mixtures has been developed that uses a time-dependent Boltzmann solution for the secondary electron distribution. The model has been improved by including HCl vibration levels for v greater than 2 and additional HCl chemistry. For the pump conditions of the electron density and HCl burnup measurements, the model predicts that the secondary electron distribution is significantly non-Maxwellian. It also supports the conclusion that the initial rapid increase of the electron density at the beginning of the pump pulse is due to the finite vibrational excitation time of HCl. The model and data also indicate that electron dissociative attachment by itself cannot adequately explain the increase in the electron density toward the end of the pulse.",

author = "Salesky, {E. T.} and Kimura, {W. D.} and F. Kannari",

year = "1987",

month = jan,

day = "1",

language = "English",

isbn = "0936659491",

publisher = "Optical Soc of America",

booktitle = "Unknown Host Publication Title",

}

TY - GEN

T1 - ROLE OF ELECTRON DISSOCIATIVE ATTACHMENT AND IMPACT DISSOCIATION OF HCL IN XECL LASERS.

AU - Salesky, E. T.

AU - Kimura, W. D.

AU - Kannari, F.

PY - 1987/1/1

Y1 - 1987/1/1

N2 - A computer model of electron-beam pumped XeCl laser mixtures has been developed that uses a time-dependent Boltzmann solution for the secondary electron distribution. The model has been improved by including HCl vibration levels for v greater than 2 and additional HCl chemistry. For the pump conditions of the electron density and HCl burnup measurements, the model predicts that the secondary electron distribution is significantly non-Maxwellian. It also supports the conclusion that the initial rapid increase of the electron density at the beginning of the pump pulse is due to the finite vibrational excitation time of HCl. The model and data also indicate that electron dissociative attachment by itself cannot adequately explain the increase in the electron density toward the end of the pulse.

AB - A computer model of electron-beam pumped XeCl laser mixtures has been developed that uses a time-dependent Boltzmann solution for the secondary electron distribution. The model has been improved by including HCl vibration levels for v greater than 2 and additional HCl chemistry. For the pump conditions of the electron density and HCl burnup measurements, the model predicts that the secondary electron distribution is significantly non-Maxwellian. It also supports the conclusion that the initial rapid increase of the electron density at the beginning of the pump pulse is due to the finite vibrational excitation time of HCl. The model and data also indicate that electron dissociative attachment by itself cannot adequately explain the increase in the electron density toward the end of the pulse.

UR - http://www.scopus.com/inward/record.url?scp=0023169274&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=0023169274&partnerID=8YFLogxK

M3 - Conference contribution

AN - SCOPUS:0023169274

SN - 0936659491

BT - Unknown Host Publication Title

PB - Optical Soc of America

ER -

ROLE OF ELECTRON DISSOCIATIVE ATTACHMENT AND IMPACT DISSOCIATION OF HCL IN XECL LASERS.

Abstract

ASJC Scopus subject areas

Other files and links

Fingerprint

Cite this