光学镊子
光学力
手性(物理)
极化(电化学)
压力梯度力
材料科学
坡印亭病媒
圆极化
纳米
物理
光学现象
激子
粒子(生态学)
消散
不对称
经典力学
凝聚态物理
动量(技术分析)
辐射压力
旋光
测距
纳米技术
雷
线极化
光学
化学物理
光电子学
光导率
光通信
介观物理学
双折射
光隔离器
光散射
不完美的
纳米光子学
分子物理学
作者
Yuzhi SHI,Chengxing Lai,Fei Hu,Xiaohao Xu,Weijie Xu,Chengfeng Li,Manuel Nieto‐Vesperinas,Alfredo Mazzulla,G. Cipparrone,Qinghua Song,Zeyong WEI,Tao He,Xinbin Cheng,C. T. Chan,Cheng‐Wei Qiu,X. Y. Cheng
标识
DOI:10.1002/adma.202517678
摘要
Light exerts optical forces on objects, finding numerous applications in physical and biomedical sciences. It is commonly known that the direction of the optical force on a single sphere is dictated by the light field. Thus, actively switching light properties such as polarization is an efficient strategy to control the locomotion of particles. Here, by exploiting the reversible optical force induced by chiral inhomogeneity, we observe self-swerving behavior in a chiral sphere embedded in water via a linearly polarized light wave. This counterintuitive optical force, arising from Poynting momentum conservation in chiral light-matter interaction, reverses direction with variations in the chirality gradient, inducing a self-swerving effect as the particle rotates. Experimentally, we observe that chiral particles, ranging from nanometers to micrometers in size, exhibit self-swerving behavior under a fixed linear polarization. Our study delves into a novel realm of optical forces in the presence of ubiquitous imperfect or inhomogeneous materials. It enriches the understanding of chiral-light interactions, and facilitates diverse applications in chiral detection, advanced optical manipulation, and micro-robots.
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