Seeded Stimulated Photorefractive Scattering

Topical Meeting on Photorefractive Materials, Effects, and Devices II Pub Date : 1900-01-01 DOI:10.1364/pmed.1990.e2

R. A. Mullen, D. J. Vickers, D. Pepper

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Abstract

Stable phase conjugate reflectivities as high as 60% have been achieved with back-seeded stimulated photorefractive scattering (SPS) in a BaTiO3 crystal having too small a gain-length product for unseeded SPS. The beam-bending and build-up dynamics of the process are demonstrated by the three top-view photographs of the crystal reproduced in Figure 1. In Figure la, there is no external seed and, in this case, no self-pumped phase conjugation; the beam refracts into an a-face of the crystal, fans sharply to an angle of about 20° with respect to the c-axis, then straightens out to exit a c-face of the crystal. In Figures 1b and 1c, the sequence of steps leading to SPS are shown in the presence of a backward seed. In Figure 1b, the fanned light exiting the crystal strikes a non-specular, diffusive-type surface, the scattering from which acts as a back-injected seed and dramatically lowers the gain-length product threshold condition for stimulated scattering. The phase-conjugate reflection in Figure 1b is in the process of building up; pump depletion is already evident in this photo. Figure 1c is a photo of the steady-state beam trajectory inside the crystal.

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种子受激光折射散射

在BaTiO3晶体中，反向种子受激光折变散射(SPS)获得了高达60%的稳定相位共轭反射率，而非种子SPS的增益长度积太小。该过程的光束弯曲和积累动力学由图1中再现的晶体的三张俯视图照片证明。在图la中，没有外部种子，在这种情况下，没有自抽运相位共轭;光束折射成晶体的a面，与c轴急剧扇形成约20°的角度，然后拉直出晶体的c面。在图1b和1c中，在存在反向种子的情况下显示了导致SPS的步骤序列。在图1b中，从晶体中射出的扇形光撞击到一个非镜面的扩散型表面，其散射起到了反向注入种子的作用，并显著降低了受激散射的增益长度乘积阈值条件。图1b中的相位共轭反射处于建立过程中;在这张照片中，水泵的枯竭已经很明显了。图1c是晶体内部稳态光束轨迹的照片。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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$Topical Meeting on Photorefractive Materials, Effects, and Devices II$

Topical Meeting on Photorefractive Materials, Effects, and Devices II

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