Valley Vortex States and Degeneracy Lifting via Photonic Higher-Band Excitation

Daohong Song; Daniel Leykam; Jing Su; Xiuying Liu; Liqin Tang; Sheng Liu; Jianlin Zhao; Nikolaos K. Efremidis; Jingjun Xu; Zhigang Chen

doi:10.1103/PhysRevLett.122.123903

Valley Vortex States and Degeneracy Lifting via Photonic Higher-Band Excitation

Daohong Song, Daniel Leykam, Jing Su, Xiuying Liu, Liqin Tang, Sheng Liu, Jianlin Zhao, Nikolaos K. Efremidis, Jingjun Xu, Zhigang Chen

School of Physical Science and Technology

Research output: Contribution to journal › Article › peer-review

26 Scopus citations

Abstract

We demonstrate valley-dependent vortex generation in photonic graphene. Without breaking inversion symmetry, the excitation of two valleys leads to the formation of an optical vortex upon Bragg reflection to the third equivalent valley, with its chirality determined by the valley degree of freedom. Vortex-antivortex pairs with valley-dependent topological charge flipping are also observed and corroborated by numerical simulations. Furthermore, we develop a three-band effective Hamiltonian model to describe the dynamics of the coupled valleys and find that the commonly used two-band model is not sufficient to explain the observed vortex degeneracy lifting. Such valley-polarized vortex states arise from high-band excitation without a synthetic-field-induced gap opening. Our results from a photonic setting may provide insight for the study of valley contrasting and Berry-phase-mediated topological phenomena in other systems.

Original language	English
Article number	123903
Journal	Physical Review Letters
Volume	122
Issue number	12
DOIs	https://doi.org/10.1103/PhysRevLett.122.123903
State	Published - 29 Mar 2019

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title = "Valley Vortex States and Degeneracy Lifting via Photonic Higher-Band Excitation",

abstract = "We demonstrate valley-dependent vortex generation in photonic graphene. Without breaking inversion symmetry, the excitation of two valleys leads to the formation of an optical vortex upon Bragg reflection to the third equivalent valley, with its chirality determined by the valley degree of freedom. Vortex-antivortex pairs with valley-dependent topological charge flipping are also observed and corroborated by numerical simulations. Furthermore, we develop a three-band effective Hamiltonian model to describe the dynamics of the coupled valleys and find that the commonly used two-band model is not sufficient to explain the observed vortex degeneracy lifting. Such valley-polarized vortex states arise from high-band excitation without a synthetic-field-induced gap opening. Our results from a photonic setting may provide insight for the study of valley contrasting and Berry-phase-mediated topological phenomena in other systems.",

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AU - Song, Daohong

AU - Leykam, Daniel

AU - Su, Jing

AU - Liu, Xiuying

AU - Tang, Liqin

AU - Liu, Sheng

AU - Zhao, Jianlin

AU - Efremidis, Nikolaos K.

AU - Xu, Jingjun

AU - Chen, Zhigang

PY - 2019/3/29

Y1 - 2019/3/29

N2 - We demonstrate valley-dependent vortex generation in photonic graphene. Without breaking inversion symmetry, the excitation of two valleys leads to the formation of an optical vortex upon Bragg reflection to the third equivalent valley, with its chirality determined by the valley degree of freedom. Vortex-antivortex pairs with valley-dependent topological charge flipping are also observed and corroborated by numerical simulations. Furthermore, we develop a three-band effective Hamiltonian model to describe the dynamics of the coupled valleys and find that the commonly used two-band model is not sufficient to explain the observed vortex degeneracy lifting. Such valley-polarized vortex states arise from high-band excitation without a synthetic-field-induced gap opening. Our results from a photonic setting may provide insight for the study of valley contrasting and Berry-phase-mediated topological phenomena in other systems.

AB - We demonstrate valley-dependent vortex generation in photonic graphene. Without breaking inversion symmetry, the excitation of two valleys leads to the formation of an optical vortex upon Bragg reflection to the third equivalent valley, with its chirality determined by the valley degree of freedom. Vortex-antivortex pairs with valley-dependent topological charge flipping are also observed and corroborated by numerical simulations. Furthermore, we develop a three-band effective Hamiltonian model to describe the dynamics of the coupled valleys and find that the commonly used two-band model is not sufficient to explain the observed vortex degeneracy lifting. Such valley-polarized vortex states arise from high-band excitation without a synthetic-field-induced gap opening. Our results from a photonic setting may provide insight for the study of valley contrasting and Berry-phase-mediated topological phenomena in other systems.

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Valley Vortex States and Degeneracy Lifting via Photonic Higher-Band Excitation

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