Propagation of Gaussian beams in anisotropic media

D. Bhawalkar, A. M. Goncharenko, R. Smith
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引用次数: 19

Abstract

The form of the Gaussian beam in an anisotropic medium has been found by solution of Maxwell's equations. For mathematical convenience a cylindrical beam (two-dimensional) is considered, with the field constant in one cross-sectional dimension and varying as the Gaussian function in the other. For uniaxial crystals, and for biaxial crystals where the propagation is in one of the principal planes, two solutions are obtained, corresponding to the ordinary and extraordinary waves. The Gaussian beam for the ordinary wave is identical to that for an isotropic medium. The extraordinary Gaussian beam is modified by double refraction and by an increase in the beam spread of 11/33. The properties of the extraordinary Gaussian beam are derived and applied to the problem of an optical resonator filled with an anisotropic medium. The low- and high-loss regions are found for the resonator together with its resonant frequencies. Two kinds of anisotropic cavity are distinguished: those where the optic axis of the medium is at 0? or 90? to the optical axis of the cavity and those where the optic axis is at 45? to the cavity axis. The three-dimensional Gaussian beam is treated by assuming that it can be represented by two orthogonal two-dimensional beams. The effect of anisotropy on the extraordinary beam gives rise to nonspherical wavefronts and elliptical cross sections. Some applications of the theory to laser problems are outlined.
高斯光束在各向异性介质中的传播
通过求解麦克斯韦方程组,得到了各向异性介质中高斯光束的形式。为了数学上的方便,我们考虑了一个圆柱形光束(二维),它在一个横截面上的场常数是高斯函数,在另一个横截面上的场常数是高斯函数。对于单轴晶体和双轴晶体,在其中一个主平面上传播,得到两个解,对应于普通波和特殊波。普通波的高斯光束与各向同性介质的高斯光束是相同的。通过双折射和光束扩展11/33的增加,对非高斯光束进行了修正。推导了高斯光束的性质,并将其应用于各向异性介质填充的光学谐振腔问题。找出了谐振器的低损耗区和高损耗区及其谐振频率。各向异性腔分为两种:介质光轴为0?还是90年?到腔的光轴和那些光轴在45度的地方?到空腔轴。假定三维高斯光束可以用两个正交的二维光束表示来处理。各向异性对非球面光束的影响产生了非球面波前和椭圆截面。概述了该理论在激光问题中的一些应用。
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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