Title :
Thermooptical compensation methods for high-power lasers
Author :
Wyss, Eduard ; Roth, Michelle ; Graf, Thomas ; Weber, Heinz P.
Author_Institution :
Inst. of Appl. Phys., Bern Univ., Switzerland
fDate :
12/1/2002 12:00:00 AM
Abstract :
Thermally induced optical effects can be exploited to generate adaptive optical devices such as self-adjusting lenses. An adaptive lens in a resonator can be used to compensate for the thermal lens in a high-power solid-state laser rod (LR) and herewith significantly improve the beam quality and increase the output-power range of solid-state lasers. With suitable materials and an appropriate design of the compensating device, resonators with self-balancing thermal lenses can be developed. In this paper, we review the material requirements for a self-adaptive compensating element and discuss a selection of suitable materials (glasses, liquids and curing gels) and schemes to compensate for the thermal lens of a Nd:YAG LR. Finally, we present a very simple and promising design of a thermooptically self-compensated laser amplifier.
Keywords :
compensation; laser beams; neodymium; optical design techniques; solid lasers; thermal lensing; thermo-optical effects; Nd:YAG laser rod; YAG:Nd; YAl5O12:Nd; adaptive lens; adaptive optical devices; beam quality; compensating device; curing gels; glasses; high-power lasers; high-power solid-state laser rod; liquids; material requirements; resonator; resonators; self-adjusting lenses; self-balancing thermal lenses; solid-state lasers; thermal lens; thermally induced optical effects; thermooptical compensation methods; thermooptically self-compensated laser amplifier; Adaptive optics; Glass; Laser beams; Lenses; Optical design; Optical devices; Optical materials; Optical resonators; Solid lasers; Thermal lensing;
Journal_Title :
Quantum Electronics, IEEE Journal of
DOI :
10.1109/JQE.2002.805105
