Title :
Microarcs as a termination mechanism of optical pulses in electric-discharge-excited KrF excimer lasers
Author :
Kushner, Mark J.
Author_Institution :
Dept. of Electr. & Comput. Eng., Illinois Univ., Urbana, IL, USA
fDate :
4/1/1991 12:00:00 AM
Abstract :
A theoretical investigation is conducted of both macroscopic (⩽mm´s to cm´s) and microscopic (<100´s μm) nonuniformities in electric field, preionization density, and halogen density as precursors to arcs and microarcs in KrF lasers. Macroscopic nonuniformities lead to volumetric arcing. Microscopic nonuniformities lead to filamentary arcs and streamers. It is found that microarcs may terminate the optical pulse due to disruption of the optical homogeneity of the plasma prior to the collapse of impedance of the discharge. Small-scale microscopic inhomogeneities (<10´s-100 μm) develop into microarcs sooner than large-scale homogeneities (>10´s-100 μm) due to the higher pressure gradient afforded by their small size. Large-scale inhomogeneities, though, are ultimately more detrimental to the performance of the laser
Keywords :
arcs (electric); excimer lasers; krypton compounds; laser theory; KrF; electric field; electric-discharge-excited KrF excimer lasers; filamentary arcs; halogen density; macroscopic nonuniformities; microarcs; microscopic nonuniformities; optical homogeneity; optical pulse termination mechanism; plasma; preionization density; theoretical investigation; volumetric arcing; Gas lasers; Impedance; Large-scale systems; Laser modes; Laser theory; Laser transitions; Microscopy; Optical pulses; Power lasers; Pulsed laser deposition;
Journal_Title :
Plasma Science, IEEE Transactions on
