贝塞尔-贝塞尔-高斯涡旋激光束

V. Kotlyar, E. Abramochkin, A. A. Kovalev
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摘要

我们获得并研究了贝塞尔-贝塞尔-高斯涡旋光束(BBG 光束),其复振幅等于高斯函数与两个贝塞尔函数的乘积,其参数用复杂的基数表示,包括圆柱坐标和一个定义强度分布形状的自由参数。如果该参数较小,则强度呈不均匀环状。如果该参数值较大,则光强呈两个弧形或 "新月形",两个弧形或 "新月形 "的凹面相互定向。在离腰部任意距离的情况下,这种光束的复振幅以显式形式得出。我们证明,BBG 光束在传播过程中的旋转速度非常快:在比瑞利长度短得多的距离上,强度分布已经旋转了近 45º,而通常情况下,涡旋高斯光束的旋转角度等于古伊相位。研究还表明,BBG 光束的参数可以控制其拓扑电荷:当参数值为正且增加时,光束的拓扑电荷也会以偶数逐步增加。此外,我们还研究了另外两种类似的涡旋 BBG 光束:一种具有四个局部强度最大值,位于笛卡尔坐标轴上;另一种具有一个强度最大值,呈新月形,其中心位于水平轴上。衍生出的三个新的非对称涡旋激光光束系列,其复振幅在离腰部的任意距离上都可以用明确的分析表达式来描述,从而扩展了可用于操纵和旋转微粒子、自由空间数据传输以及量子信息学的激光光束的种类。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Bessel-Bessel-Gaussian vortex laser beams
We obtain and investigate Bessel-Bessel-Gaussian vortex beams (BBG beams) with the complex amplitude being equal to a product of the Gaussian function with two Bessel functions, whose arguments are expressed as complicated radicals including the cylindrical coordinates and a free parameter that defines the shape of the intensity distribution. If this parameter is small, the intensity has the shape of an inhomogeneous ring. For larger values of this parameter, the intensity has the shape of two arcs or 'crescents', oriented by their concave sides to each other. The complex amplitude of such beams is derived in explicit form for an arbitrary distance from the waist. We demonstrate that the BBG beams rotate upon propagation anomalously fast: at a distance much shorter than the Rayleigh length, the intensity distribution is already rotated by almost 45º, whereas typically, the rotation angle of vortex Gaussian beams is equal to the Gouy phase. It is also shown that the parameter of the BBG beam allows controlling its topological charge: when the parameter value is positive and increases, the beam topological charge also increases stepwise by an even number. Besides, we study two other similar vortex BBG beams: either with four local intensity maxima, lying on the Cartesian coordinates axes, or with one intensity maximum with a crescent shape, whose center is on the horizontal axis. The derived three new families of asymmetric vortex laser beams, whose complex amplitude is described by explicit analytical expressions at an arbitrary distance from the waist, extend the variety of laser beams that can be used for manipulating and rotating microparticles, free space data transmission, and in quantum informatics.
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