{"title":"Optical near-field measurement for spin-orbit interaction of light","authors":"Peng Shi, Aiping Yang, Fanfei Meng, Jiashuo Chen, Yuquan Zhang, Zhenwei Xie, Luping Du, Xiaocong Yuan","doi":"10.1016/j.pquantelec.2021.100341","DOIUrl":null,"url":null,"abstract":"<div><p><span><span>Since the seminal work by J. H. Poynting, light has been known to carry momentum and angular momentum. The typical dynamical features of light and its interactions—termed spin–orbit interactions (SOIs), which have been investigated intensely over the last 30 years—play a crucial role in various light-matter interactions, for example: spin </span>Hall effect<span><span><span>, spin–orbit conversion, helicity-controlled unidirectional excitation of light, and their inverse effects, which leads to plenty of applications including optical manipulation, communications, imaging, sensing, nanometrology<span>, on-chip optoelectronic technologies and interdisciplinary researches. In particular, the SOI of light in isotropic </span></span>inhomogeneous media is a fine, subwavelength effect accomplished through the intrinsic coupling between light's phase, polarization and position. Therefore, the traditional methods of near-field measurements, such as </span>near field<span> scanning optical microscopy (NSOM), have been widely employed to reveal the optical SOIs intuitively by measuring the intensity of light. Very recently, with modern advanced nanofabrication techniques, many measurement techniques based on </span></span></span>nanoparticles<span>, nanoantennas, and nanoprobes of special designs have been proposed to understand the optical SOIs visually by characterizing the polarization and spin/orbital features of light. This endeavor has led to the development of chiral quantum optics<span>, spin optics<span>, and topological photonics, and resulted in novel applications requiring optical manipulations and angular momentum communications, chiral imaging, nanometrology, and robust spin-based devices and techniques for quantum technologies. Here, we review the near-field techniques for measurements of optical SOIs together with their potential applications. We start with a theoretical overview of momentum and angular momentum properties of generic optical fields and typical phenomena involving optical SOIs. Then, we overview the theoretical basis and latest achievements of the near-field measurement techniques, including NSOM, optical manipulations, nanoantenna, and nanoprobes of special designs, all relevant to optical SOIs. A comprehensive classification is then constructed of all known methods of optical near-field measurements for the SOI of light and novel techniques identified for future applications.</span></span></span></p></div>","PeriodicalId":414,"journal":{"name":"Progress in Quantum Electronics","volume":"78 ","pages":"Article 100341"},"PeriodicalIF":7.4000,"publicationDate":"2021-08-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://sci-hub-pdf.com/10.1016/j.pquantelec.2021.100341","citationCount":"15","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Progress in Quantum Electronics","FirstCategoryId":"101","ListUrlMain":"https://www.sciencedirect.com/science/article/pii/S0079672721000264","RegionNum":1,"RegionCategory":"物理与天体物理","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"ENGINEERING, ELECTRICAL & ELECTRONIC","Score":null,"Total":0}
引用次数: 15
Abstract
Since the seminal work by J. H. Poynting, light has been known to carry momentum and angular momentum. The typical dynamical features of light and its interactions—termed spin–orbit interactions (SOIs), which have been investigated intensely over the last 30 years—play a crucial role in various light-matter interactions, for example: spin Hall effect, spin–orbit conversion, helicity-controlled unidirectional excitation of light, and their inverse effects, which leads to plenty of applications including optical manipulation, communications, imaging, sensing, nanometrology, on-chip optoelectronic technologies and interdisciplinary researches. In particular, the SOI of light in isotropic inhomogeneous media is a fine, subwavelength effect accomplished through the intrinsic coupling between light's phase, polarization and position. Therefore, the traditional methods of near-field measurements, such as near field scanning optical microscopy (NSOM), have been widely employed to reveal the optical SOIs intuitively by measuring the intensity of light. Very recently, with modern advanced nanofabrication techniques, many measurement techniques based on nanoparticles, nanoantennas, and nanoprobes of special designs have been proposed to understand the optical SOIs visually by characterizing the polarization and spin/orbital features of light. This endeavor has led to the development of chiral quantum optics, spin optics, and topological photonics, and resulted in novel applications requiring optical manipulations and angular momentum communications, chiral imaging, nanometrology, and robust spin-based devices and techniques for quantum technologies. Here, we review the near-field techniques for measurements of optical SOIs together with their potential applications. We start with a theoretical overview of momentum and angular momentum properties of generic optical fields and typical phenomena involving optical SOIs. Then, we overview the theoretical basis and latest achievements of the near-field measurement techniques, including NSOM, optical manipulations, nanoantenna, and nanoprobes of special designs, all relevant to optical SOIs. A comprehensive classification is then constructed of all known methods of optical near-field measurements for the SOI of light and novel techniques identified for future applications.
自从J. H. Poynting的开创性工作以来,人们已经知道光携带动量和角动量。光及其相互作用的典型动力学特征——被称为自旋轨道相互作用(SOIs)——在过去30年里得到了广泛的研究,在各种光-物质相互作用中起着至关重要的作用,例如:自旋霍尔效应、自旋轨道转换、螺旋控制的光单向激发及其逆效应,在光学操纵、通信、成像、传感、纳米计量、片上光电技术和跨学科研究等领域有着广泛的应用。特别是,光在各向同性非均匀介质中的SOI是一种精细的亚波长效应,通过光的相位、偏振和位置之间的内在耦合来实现。因此,传统的近场测量方法,如近场扫描光学显微镜(NSOM),已被广泛采用,通过测量光的强度来直观地揭示光学SOIs。近年来,随着现代先进的纳米制造技术的发展,人们提出了许多基于纳米粒子、纳米天线和特殊设计的纳米探针的测量技术,通过表征光的偏振和自旋/轨道特征来直观地理解光学SOIs。这一努力导致了手性量子光学、自旋光学和拓扑光子学的发展,并导致了新的应用,需要光学操作和角动量通信、手性成像、纳米计量学和强大的基于自旋的量子技术设备和技术。在这里,我们回顾了近场测量技术及其潜在的应用。我们首先从理论上概述了一般光场的动量和角动量性质以及涉及光学SOIs的典型现象。在此基础上,综述了近场测量技术的理论基础和最新进展,包括NSOM、光学操作、纳米天线和特殊设计的纳米探针等。然后,对所有已知的光SOI光学近场测量方法和确定用于未来应用的新技术进行了全面分类。
期刊介绍:
Progress in Quantum Electronics, established in 1969, is an esteemed international review journal dedicated to sharing cutting-edge topics in quantum electronics and its applications. The journal disseminates papers covering theoretical and experimental aspects of contemporary research, including advances in physics, technology, and engineering relevant to quantum electronics. It also encourages interdisciplinary research, welcoming papers that contribute new knowledge in areas such as bio and nano-related work.