Optical transmission processes in a thermally driven protected multi-component device

Gregory J. Kowalski; Landa Hoke; David Colanto; Masato Nakashima; Barry S. DeCristofano

doi:10.1117/12.452721

16 January 2002 Optical transmission processes in a thermally driven protected multicomponent device

Gregory J. Kowalski, Landa Hoke, David Colanto, Masato Nakashima, Barry S. DeCristofano

Proceedings Volume 4462, Nonlinear Optical Transmission Processes and Organic Photorefractive Materials; (2002) https://doi.org/10.1117/12.452721
Event: International Symposium on Optical Science and Technology, 2001, San Diego, CA, United States

Abstract

A strategy for protecting and improving the performance of a nonlinear optical device exposed to a high-energy beam is numerically investigated. In this strategy, a thermally stimulated defocusing material is used in combination with a RSA material. To test this new approach, the ability of a CS₂ cell dyed with a liner absorber material to protect a NLO device is determined using calculated values of beam and aperture transmission and the temperature distribution in the NLO device. The results demonstrate that the strategy provides thermal protection and marginally reduces the aperture transmission. These current calculations suggests that other approaches, such as multi-cell devices, may be more effective at providing thermal protection and reducing beam transmission. However, this current approach needs further investigation at other linear transmissions and in addition might be combined with other approaches, such as multiple layers to provide enhanced protection.

Citation Download Citation

Gregory J. Kowalski, Landa Hoke, David Colanto, Masato Nakashima, and Barry S. DeCristofano "Optical transmission processes in a thermally driven protected multicomponent device", Proc. SPIE 4462, Nonlinear Optical Transmission Processes and Organic Photorefractive Materials, (16 January 2002); https://doi.org/10.1117/12.452721

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