Paper
23 November 2017 CW laser damage testing of RAR nano-textured fused silica and YAG
Bruce D. MacLeod, Douglas S. Hobbs, Anthony D. Manni, Ernest Sabatino III, David M. Bernot, Sage DeFrances, Joseph A. Randi, Jeffrey Thomas
Author Affiliations +
Abstract
A study of the continuous wave (CW) laser induced damage threshold (LiDT) of fused silica and yttrium aluminum garnet (YAG) optics was conducted to further illustrate the enhanced survivability within high power laser systems of an anti-reflection (AR) treatment consisting of randomly distributed surface relief nanostructures (RAR). A series of three CW LiDT tests using the 1070nm wavelength, 16 KW fiber laser test bed at Penn State Electro-Optic Center (PSEOC) were designed and completed, with improvements in the testing protocol, areal coverage, and maximum exposure intensities implemented between test cycles. Initial results for accumulated power, stationary site exposures of RAR nano-textured optics showed no damage and low surface temperatures similar to the control optics with no AR treatment. In contrast, optics with thin-film AR coatings showed high surface temperatures consistent with absorption by the film layers. Surface discriminating absorption measurements made using the Photothermal Common-path Interferometry (PCI) method, showed zero added surface absorption for the RAR nanotextured optics, and absorption levels in the 2-5 part per million range for thin-film AR coated optics. In addition, the surface absorption of thin-film AR coatings was also found to have localized absorption spikes that are likely pre-cursors for damage. Subsequent CW LiDT testing protocol included raster scanning an increased intensity focused beam over the test optic surface where it was found that thin-film AR coated optics damaged at intensities in the 2 to 5 MW/cm2 range with surface temperatures over 250C during the long-duration exposures. Significantly, none of the 10 RAR nano-textured fused silica optics tested could be damaged up to the maximum system intensity of 15.5 MW/cm2, and surface temperatures remained low. YAG optics tested during the final cycle exhibited a similar result with RAR nano-textured surfaces surviving intensities over 3 times higher than thin-film AR coated surfaces. This result was correlated with PCI measurements that also show zero-added surface absorption for the RAR nano-textured YAG optics.
© (2017) COPYRIGHT Society of Photo-Optical Instrumentation Engineers (SPIE). Downloading of the abstract is permitted for personal use only.
Bruce D. MacLeod, Douglas S. Hobbs, Anthony D. Manni, Ernest Sabatino III, David M. Bernot, Sage DeFrances, Joseph A. Randi, and Jeffrey Thomas "CW laser damage testing of RAR nano-textured fused silica and YAG", Proc. SPIE 10447, Laser-Induced Damage in Optical Materials 2017, 1044705 (23 November 2017); https://doi.org/10.1117/12.2280498
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KEYWORDS
Absorption

Thin films

YAG lasers

Continuous wave operation

Thin film coatings

Silica

Laser induced damage

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