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Two-Dimensional Computational Model of Discharge Uniformity in Radio-Frequency-Excited CO2 Slab Lasers With High Aspect Ratio Electrodes

Spindler, G. (2003) Two-Dimensional Computational Model of Discharge Uniformity in Radio-Frequency-Excited CO2 Slab Lasers With High Aspect Ratio Electrodes. IEEE Journal of Quantum Electronics, 39 (2), pp. 343-349.

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Abstract

A finite difference scheme for the numerical solution of Maxwell's equations in the time domain is utilized for the optimization of discharge uniformity in radio frequency (RF)-excited CO2 slab lasers with high aspect ratio electrodes. The field solver can be coupled to standard RF discharge models. The model may be regarded as a natural generalization of the successful transmission line method to two dimensions.

Document Type:Article
Additional Information: LIDO-Berichtsjahr=2003,
Title:Two-Dimensional Computational Model of Discharge Uniformity in Radio-Frequency-Excited CO2 Slab Lasers With High Aspect Ratio Electrodes
Authors:
AuthorsInstitution or Email of Authors
Spindler, G.UNSPECIFIED
Date:2003
Journal or Publication Title:IEEE Journal of Quantum Electronics
Refereed publication:Yes
In ISI Web of Science:Yes
Volume:39
Page Range:pp. 343-349
Status:Published
Keywords:Diffusion-cooled CO2 lasers, RF discharges, RF-excited CO2 lasers
HGF - Research field:Energy
HGF - Program:Aeronautics
HGF - Program Themes:other
DLR - Research area:Energy
DLR - Program:L - no assignement
DLR - Research theme (Project):L - Laser Research and Technology
Location: Stuttgart
Institutes and Institutions:Institute of Technical Physics
Deposited By: Dr.rer.nat. Hans-Albert Eckel
Deposited On:16 Sep 2005
Last Modified:06 Jan 2010 14:48

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