Wavefront distortions caused by the convection of heated ambient air in front of the laser crystal induce severe pump-power-dependent misalignment in thin-disk laser (TDL) resonators. This effect is particularly pronounced in fundamental mode operation and limits the output power when no realignment of the resonator is possible during operation. In this Letter, we present a new approach to passively compensate for this misalignment instability by exploiting the spectral dispersion of a highly efficient grating-waveguide mirror used as a cavity end-mirror in a Littrow configuration. By this, it was possible to almost triple the output power of a fundamental mode Yb:LuAG TDL pumped at 969 nm.
%0 Journal Article
%1 dietrich2017passive
%A Dietrich, Tom
%A Piehler, Stefan
%A Röcker, Christoph
%A Rumpel, Martin
%A Abdou-Ahmed, Marwan
%A Graf, Thomas
%D 2017
%I Optical Society of America
%J Optics Letters
%K grating myown peer thindisklaser
%N 17
%P 3263--3266
%R https://doi.org/10.1364/OL.42.003263
%T Passive compensation of the misalignment instability caused by air convection in thin-disk lasers
%U https://www.osapublishing.org/ol/abstract.cfm?uri=ol-42-17-3263
%V 42
%X Wavefront distortions caused by the convection of heated ambient air in front of the laser crystal induce severe pump-power-dependent misalignment in thin-disk laser (TDL) resonators. This effect is particularly pronounced in fundamental mode operation and limits the output power when no realignment of the resonator is possible during operation. In this Letter, we present a new approach to passively compensate for this misalignment instability by exploiting the spectral dispersion of a highly efficient grating-waveguide mirror used as a cavity end-mirror in a Littrow configuration. By this, it was possible to almost triple the output power of a fundamental mode Yb:LuAG TDL pumped at 969 nm.
@article{dietrich2017passive,
abstract = {Wavefront distortions caused by the convection of heated ambient air in front of the laser crystal induce severe pump-power-dependent misalignment in thin-disk laser (TDL) resonators. This effect is particularly pronounced in fundamental mode operation and limits the output power when no realignment of the resonator is possible during operation. In this Letter, we present a new approach to passively compensate for this misalignment instability by exploiting the spectral dispersion of a highly efficient grating-waveguide mirror used as a cavity end-mirror in a Littrow configuration. By this, it was possible to almost triple the output power of a fundamental mode Yb:LuAG TDL pumped at 969 nm.},
added-at = {2018-04-20T12:18:30.000+0200},
author = {Dietrich, Tom and Piehler, Stefan and R{\"o}cker, Christoph and Rumpel, Martin and Abdou-Ahmed, Marwan and Graf, Thomas},
biburl = {https://puma.ub.uni-stuttgart.de/bibtex/2d97d8e36629754fceb0f79ba7eab55c5/thomas_graf},
doi = {https://doi.org/10.1364/OL.42.003263},
interhash = {f65b42a2bff00a2a42226fd73a387ac1},
intrahash = {d97d8e36629754fceb0f79ba7eab55c5},
journal = {Optics Letters},
keywords = {grating myown peer thindisklaser},
number = 17,
pages = {3263--3266},
publisher = {Optical Society of America},
timestamp = {2018-04-20T10:18:33.000+0200},
title = {Passive compensation of the misalignment instability caused by air convection in thin-disk lasers},
url = {https://www.osapublishing.org/ol/abstract.cfm?uri=ol-42-17-3263},
volume = 42,
year = 2017
}