Vector-Mode Decay in Atmospheric Turbulence: An Analysis Inspired by Quantum Mechanics

arXiv: Optics Pub Date : 2020-11-30 DOI:10.1103/PHYSREVAPPLIED.15.034030

I. Nape, N. Mashaba, Nokwazi Mphuthi, S. Jayakumar, S. Bhattacharya, A. Forbes

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引用次数: 5

Abstract

Vector beams are inhomogeneously polarized optical fields with nonseparable, quantum-like correlations between their polarisation and spatial components, and hold tremendous promise for classical and quantum communication across various channels, e.g. the atmosphere, underwater, and in optical fibre. Here we show that by exploiting their quantum-like features by virtue of the nonseparability of the field, the decay of both the polarisation and spatial components can be studied in tandem. In particular, we invoke the principle of channel state duality to show that the degree of nonseparability of any vector mode is purely determined by that of a maximally nonseparable one, which we confirm using orbital angular momentum (OAM) as an example for topological charges of l = 1 and l = 10 in a turbulent atmosphere. A consequence is that the well-known cylindrical vector vortex beams are sufficient to predict the behaviour of all vector OAM states through the channel, and find that the rate of decay in vector quality decreases with increasing OAM value, even though the spread in OAM is opposite, increasing with OAM. Our approach offers a fast and easy probe of noisy channels, while at the same time revealing the power of quantum tools applied to classical light.

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大气湍流中的矢量模衰减:受量子力学启发的分析

矢量光束是一种非均匀偏振光场，其偏振和空间分量之间具有不可分离的量子相关性，在各种信道(例如大气、水下和光纤)的经典和量子通信中具有巨大的前景。在这里，我们表明，通过利用它们的量子样特征，凭借场的不可分性，极化和空间分量的衰减可以串联研究。特别地，我们援引通道态对偶原理来证明任何矢量模的不可分度纯粹由最大不可分模的不可分度决定，我们用轨道角动量(OAM)作为湍流大气中l = 1和l = 10的拓扑电荷的例子来证实这一点。结果是，众所周知的圆柱形矢量涡旋光束足以预测所有矢量OAM状态通过通道的行为，并发现矢量质量的衰减率随着OAM值的增加而降低，尽管OAM中的扩散相反，随着OAM的增加而增加。我们的方法提供了一种快速而简单的噪声通道探测，同时揭示了应用于经典光的量子工具的力量。

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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arXiv: Optics

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