Stable-unstable resonators for annular gain media

Dietmar Ehrlichmann; Uwe Habich; Heinz-Dieter Plum; Peter Loosen

doi:10.1117/12.184626

16 August 1994 Stable-unstable resonators for annular gain media

Dietmar Ehrlichmann, Uwe Habich, Heinz-Dieter Plum, Peter Loosen

Proceedings Volume 2206, High-Power Gas and Solid State Lasers; (1994) https://doi.org/10.1117/12.184626
Event: Europto High Power Lasers and Laser Applications V, 1994, Vienna, Austria

Abstract

Annular gain media offer various advantages to the design of lasers. The advantages comprise efficient laser excitation by internal pumping sources for solid state lasers and large discharge surfaces for diffusion-cooling of high power CO₂-lasers. To benefit from these advantages it is necessary to find a suitable resonator. The presented solution to the resonator problem consists of a hybrid resonator which is stable in radial and unstable in azimuthal direction. Basically, it can be considered as the annular equivalent of the well-known stable-unstable slab resonator. A geometrical model of the resonator indicates that for proper resonator function the mirror shapes must respect certain constraints. A diffraction model of the loaded resonator gives detailed information on the beam properties and extraction efficiencies. To reduce the computational effort for beam propagation an approximate diffraction kernel for annular beams has been used. Experimental data on a 1 kW diffusion-cooled CO₂-laser are reported.

Citation Download Citation

Dietmar Ehrlichmann, Uwe Habich, Heinz-Dieter Plum, and Peter Loosen "Stable-unstable resonators for annular gain media", Proc. SPIE 2206, High-Power Gas and Solid State Lasers, (16 August 1994); https://doi.org/10.1117/12.184626

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