Title :
Fast-axial-flow CO2 slab laser with a narrow-gap RF discharge operating at high pressure
Author :
Markille, G.A.J. ; Baker, H.J. ; Betterton, J.G. ; Hall, D.R.
Author_Institution :
Dept. of Phys., Heriot-Watt Univ., Edinburgh, UK
fDate :
8/1/1999 12:00:00 AM
Abstract :
A fast-axial-flow carbon dioxide laser is operated with a rectangular cross section, radio frequency excited, slab discharge. The narrow electrode gap and the series capacitance of the discharge tube walls produce excellent discharge stability at higher input power density and pressure than in conventional fast-axial-flow lasers. For a single-section test discharge, the mass flow per unit cross-sectional area is improved by high-pressure operation and the mass flow choking effect at sonic gas exit velocity is avoided. For CW operation, the discharge power density has been increased to 200 W·cm-3 and laser operation demonstrated at a pressure of 500 torr. In pulsed operation at pressures of 300-400 torr, repetition frequencies of 15 kHz have been achieved with the pulse duration reduced to 15-25 μs, suitable for materials processing of low thermal conductivity materials
Keywords :
carbon compounds; gas lasers; high-frequency discharges; laser beams; laser materials processing; laser modes; 15 kHz; 15 to 25 mus; 300 to 400 torr; 500 torr; CO2; CO2 slab laser; CW operation; cross-sectional area; discharge power density; discharge stability; discharge tube walls; fast-axial-flow laser; fast-axial-flow lasers; fast-axial-flow slab laser; high pressure operation; high-pressure operation; input power density; input pressure; laser operation; low thermal conductivity materials; mass flow; mass flow choking effect; materials processing; narrow electrode gap; narrow-gap RF discharge; pulse duration; pulsed operation; rectangular cross section radio frequency excited slab discharge; repetition frequencies; series capacitance; single-section test discharge; sonic gas exit velocity; Capacitance; Carbon dioxide; Electrodes; Gas lasers; Laser excitation; Laser stability; Power lasers; Radio frequency; Slabs; Thermal conductivity;
Journal_Title :
Quantum Electronics, IEEE Journal of
