28 October 2005 Improved multi-layer glass-bonded QPM GaAs crystals for non-linear wavelength conversion into the mid-infrared
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Abstract
Optical parametric oscillators (OPOs) offer a route to powerful tunable output in the mid-infrared (mid-IR). Mid-IR OPOs exploit wavelength conversion of near-infrared lasers within non-linear optical materials. A new approach to engineering suitable non-linear OPO materials is being developed as an alternative to conventional chalcopyrite crystals such as ZnGeP2. These new materials use commercially available, high-optical quality gallium arsenide (GaAs) wafers and a novel glass-bonding (GB) process to assemble quasi-phase matched (QPM) multilayer structures. The assembled QPM GaAs stack must have low optical loss and a large useable aperture and needs to be produced reliably with a minimum of 50 layers. Results from a recent sequence of 50-layer GBGaAs stack fabrication will be presented. Of the six stacks successfully bonded two had a useable aperture of approximately 20 mm2 (40% of the maximum available). Of these, one has the lowest absorption and transmission loss per layer (0.07% measured at 2 μm) of any multi-layer glass-bonded QPM GaAs stack produced to date. By adjusting the load distribution at the edges of the stack during bonding the useable optical aperture was increased to nearly 90%. Results from non-linear wavelength conversion experiments into the mid-infrared using multi-layer GBGaAs crystals will be presented.
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Paul D. Mason, Paul D. Mason, Euan J. McBrearty, Euan J. McBrearty, Pamela J. Webber, Pamela J. Webber, Brian J. Perrett, Brian J. Perrett, Martin R. Wedd, Martin R. Wedd, David A. Orchard, David A. Orchard, } "Improved multi-layer glass-bonded QPM GaAs crystals for non-linear wavelength conversion into the mid-infrared", Proc. SPIE 5990, Optically Based Materials and Optically Based Biological and Chemical Sensing for Defence II, 599005 (28 October 2005); doi: 10.1117/12.633521; https://doi.org/10.1117/12.633521
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