Title :
Return current in large aperture electron-beam-excited KrF lasers
Author :
Kushner, Mark J.
Author_Institution :
Dept. of Electr. & Comput. Eng., Illinois Univ., Champaign, IL, USA
fDate :
9/1/1990 12:00:00 AM
Abstract :
Results from a model for an e-beam excited KrF laser are presented, and the effects of return currents on plasma parameters and laser performance are discussed. The author finds that the joule heating caused by the return currents, expressed as a fraction of total power deposition, increases with increasing halogen density, increasing aperture size, increasing pressure, and decreasing power deposition. The return current electric field causes a decrease in the rate coefficients for dissociate recombination and attachment and an increase in the rate of multistep ionization. As a result, the electron density near the foil increases by more than tens of percentage points. The laser intensity in those regions also increases. These effects are practically important in lasers having apertures exceeding 1 m
Keywords :
electric current; excimer lasers; krypton compounds; laser theory; molecular electron impact ionisation; 1 m; KrF; aperture size; dissociate recombination; dissociative attachment; electric field; electron density; foil; halogen density; joule heating; large aperture electron-beam-excited KrF lasers; laser intensity; laser models; laser performance; multistep ionization; plasma parameters; power deposition; rate coefficients; return currents; total power deposition; Apertures; Electric potential; Electron beams; Gas lasers; Heating; Laser beams; Laser excitation; Laser fusion; Laser modes; Pump lasers;
Journal_Title :
Quantum Electronics, IEEE Journal of
