方位和径向偏振光束的组合:螺旋和动量密度、生成和最佳手性光

IF 3.7 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY Advanced Photonics Research Pub Date : 2024-01-08 DOI:10.1002/adpr.202300265
Albert Herrero-Parareda, Filippo Capolino
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引用次数: 0

摘要

本文研究了方位径向偏振光束(ARPB)的光学特性,ARPB 是方位偏振光束和径向偏振光束的叠加。这一条件被称为 "最佳手性光",因为它代表了给定能量密度下可能存在的最大局部手性。ARPB 的横向场在横向平面上占主导地位,但在光束轴上却消失了,在光束轴上的磁场和电场纯粹是纵向的,这导致光学手性密度和能量密度完全来自光束轴上的纵向场分量,在光束轴上的线性和角动量密度消失了。ARPB 在光束轴附近没有相位变化,但在光束轴附近会产生功率流,从而导致纵向轨道动量密度。本文介绍了 ARPB 的简明符号,并提供了场量,尤其是最佳手性配置的场量。ARPB 显示了仅依靠其纵向电场和磁场沿光束轴对手性粒子进行精确的一维手性探测和对映体分离的前景。在此,我们提供了一种生成具有可控手性和轨道角动量的 ARPB 的装置。
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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The Combination of the Azimuthally and Radially Polarized Beams: Helicity and Momentum Densities, Generation, and Optimal Chiral Light

Herein, the optical properties of the azimuthally radially polarized beam (ARPB), a superposition of an azimuthally polarized beam and a radially polarized beam, which can be tuned to exhibit maximum chirality at a given energy density, are investigated. This condition is called “optimal chiral light” since it represents the maximum possible local chirality at a given energy density. The transverse fields of an ARPB dominate in the transverse plane but vanish on the beam axis, where the magnetic and electric fields are purely longitudinal, leading to an optical chirality density and an energy density that stem solely from the longitudinal field components on the beam axis, where the linear and angular momentum densities vanish. The ARPB does not have a phase variation around the beam axis and nonetheless exhibits a power flow around the beam axis that causes a longitudinal orbital angular momentum density. Herein, a concise notation for the ARPB is introduced and field quantities are provided, especially for the optimally chiral configuration. The ARPB shows promise for precise 1D chirality probing and enantioseparation of chiral particles along the beam axis, relying solely on its longitudinal electric and magnetic fields. Herein, a setup is provided to generate ARPBs with controlled chirality and orbital angular momentum.

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