Hidden Symmetry and Invariance in Optical Forces

Yikun Jiang; Haoze Lin; Xiao Li; Jun Chen; Junjie Du; Jack Ng

doi:10.1021/acsphotonics.9b00746

Hidden Symmetry and Invariance in Optical Forces

Yikun Jiang, Haoze Lin, Xiao Li, Jun Chen, Junjie Du, Jack Ng^*

^*Corresponding author for this work

Department of Physics

Research output: Contribution to journal › Journal article › peer-review

19 Citations (Scopus)

Abstract

Like any physical quantity whose symmetry properties mimic its source, the optical force acting on a neutral spherical particle has a symmetry that mimics the incident field. The optical force consists of the gradient force and the scattering force. Here, we explicitly show that in optical lattices, the in-plane gradient force and scattering force have additional even and odd symmetries upon 2N-fold rotation, respectively, which are not shared by the incident field that is N-fold discrete rotationally symmetric. Similar hidden symmetries, namely, even and odd symmetries upon reflection about the focal plane, are also found in particles illuminated by a Gaussian beam, suggesting that it is a general property of the optical force. These are verified numerically in multiple examples and analytically for three incident plane waves, by which we also discover that the profiles of the gradient force and the scattering force are invariant with respect to material composition and particle size for a spherical particle. As such, one can tune the polarization to almost completely "turn off" either gradient force or scattering force, leaving behind a purely irrotational or solenoidal force field, opening a new freedom to control the conservativeness of optical forces.

Original language	English
Pages (from-to)	2749-2756
Number of pages	8
Journal	ACS Photonics
Volume	6
Issue number	11
DOIs	https://doi.org/10.1021/acsphotonics.9b00746
Publication status	Published - 20 Nov 2019

User-Defined Keywords

conservative force
gradient force
nonconservative force
optical force decomposition
optical trapping
scattering force

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10.1021/acsphotonics.9b00746

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title = "Hidden Symmetry and Invariance in Optical Forces",

abstract = "Like any physical quantity whose symmetry properties mimic its source, the optical force acting on a neutral spherical particle has a symmetry that mimics the incident field. The optical force consists of the gradient force and the scattering force. Here, we explicitly show that in optical lattices, the in-plane gradient force and scattering force have additional even and odd symmetries upon 2N-fold rotation, respectively, which are not shared by the incident field that is N-fold discrete rotationally symmetric. Similar hidden symmetries, namely, even and odd symmetries upon reflection about the focal plane, are also found in particles illuminated by a Gaussian beam, suggesting that it is a general property of the optical force. These are verified numerically in multiple examples and analytically for three incident plane waves, by which we also discover that the profiles of the gradient force and the scattering force are invariant with respect to material composition and particle size for a spherical particle. As such, one can tune the polarization to almost completely {"}turn off{"} either gradient force or scattering force, leaving behind a purely irrotational or solenoidal force field, opening a new freedom to control the conservativeness of optical forces.",

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author = "Yikun Jiang and Haoze Lin and Xiao Li and Jun Chen and Junjie Du and Jack Ng",

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AU - Jiang, Yikun

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AU - Du, Junjie

AU - Ng, Jack

N1 - Funding information: This work was support by the NSFC through 11574055, 11474098, 11304260, and 11674204, the National Key R&D Programs of China through 2016YFA0301103 and 2018YFA0306201, and HK RGC through Grants AoE/P-02/12 and C6013-18GF. Publisher Copyright: © 2019 American Chemical Society.

PY - 2019/11/20

Y1 - 2019/11/20

N2 - Like any physical quantity whose symmetry properties mimic its source, the optical force acting on a neutral spherical particle has a symmetry that mimics the incident field. The optical force consists of the gradient force and the scattering force. Here, we explicitly show that in optical lattices, the in-plane gradient force and scattering force have additional even and odd symmetries upon 2N-fold rotation, respectively, which are not shared by the incident field that is N-fold discrete rotationally symmetric. Similar hidden symmetries, namely, even and odd symmetries upon reflection about the focal plane, are also found in particles illuminated by a Gaussian beam, suggesting that it is a general property of the optical force. These are verified numerically in multiple examples and analytically for three incident plane waves, by which we also discover that the profiles of the gradient force and the scattering force are invariant with respect to material composition and particle size for a spherical particle. As such, one can tune the polarization to almost completely "turn off" either gradient force or scattering force, leaving behind a purely irrotational or solenoidal force field, opening a new freedom to control the conservativeness of optical forces.

AB - Like any physical quantity whose symmetry properties mimic its source, the optical force acting on a neutral spherical particle has a symmetry that mimics the incident field. The optical force consists of the gradient force and the scattering force. Here, we explicitly show that in optical lattices, the in-plane gradient force and scattering force have additional even and odd symmetries upon 2N-fold rotation, respectively, which are not shared by the incident field that is N-fold discrete rotationally symmetric. Similar hidden symmetries, namely, even and odd symmetries upon reflection about the focal plane, are also found in particles illuminated by a Gaussian beam, suggesting that it is a general property of the optical force. These are verified numerically in multiple examples and analytically for three incident plane waves, by which we also discover that the profiles of the gradient force and the scattering force are invariant with respect to material composition and particle size for a spherical particle. As such, one can tune the polarization to almost completely "turn off" either gradient force or scattering force, leaving behind a purely irrotational or solenoidal force field, opening a new freedom to control the conservativeness of optical forces.

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Hidden Symmetry and Invariance in Optical Forces

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