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Main Authors: Liu, Jian-Wei, Liu, Gui-Geng, Zhang, Bo, Mo, Hao-Chang, Li, Ruifeng, Li, Mingwei, Chen, Xiao-Dong, Zhang, Baile, Chen, Wen-Jie, Dong, Jian-Wen
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2505.14383
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author Liu, Jian-Wei
Liu, Gui-Geng
Zhang, Bo
Mo, Hao-Chang
Li, Ruifeng
Li, Mingwei
Chen, Xiao-Dong
Zhang, Baile
Chen, Wen-Jie
Dong, Jian-Wen
author_facet Liu, Jian-Wei
Liu, Gui-Geng
Zhang, Bo
Mo, Hao-Chang
Li, Ruifeng
Li, Mingwei
Chen, Xiao-Dong
Zhang, Baile
Chen, Wen-Jie
Dong, Jian-Wen
contents Valleytronics has emerged as a promising paradigm, enabling comprehensive control of the valley degree of freedom (DoF) for energy-efficient and high-speed information processing. However, backscattering-induced valley depolarization remains a fundamental limitation, stemming from the weak topological protection of the valley Hall phase. Here, we propose and demonstrate the concept of chiral valley edge states, which integrate the robust unidirectional chiral edge states with valley DoF. By controlling the valley Dirac masses, we selectively confine the chiral edge band around a single valley, enabling back-scattering-free propagation while imparting valley polarization. Our strategy not only addresses the valley depolarization issue but also introduces a unique functionality--valley multiplexing--allowing independent and arbitrary control over waves associated with different valley polarizations. We demonstrate our concept experimentally within hybrid topological photonic crystal systems composed of Chern and valley photonic crystals. Moreover, two key components for valley multiplexing are demonstrated: a valley (de-)multiplexer and a valley-locked waveguide crossing, facilitating non-interfering signal routing. Our results establish a novel interplay between the topological quantum Hall and valley Hall phases, offering a new framework for robust valley-based information processing.
format Preprint
id arxiv_https___arxiv_org_abs_2505_14383
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Chiral Valley Edge States
Liu, Jian-Wei
Liu, Gui-Geng
Zhang, Bo
Mo, Hao-Chang
Li, Ruifeng
Li, Mingwei
Chen, Xiao-Dong
Zhang, Baile
Chen, Wen-Jie
Dong, Jian-Wen
Optics
Valleytronics has emerged as a promising paradigm, enabling comprehensive control of the valley degree of freedom (DoF) for energy-efficient and high-speed information processing. However, backscattering-induced valley depolarization remains a fundamental limitation, stemming from the weak topological protection of the valley Hall phase. Here, we propose and demonstrate the concept of chiral valley edge states, which integrate the robust unidirectional chiral edge states with valley DoF. By controlling the valley Dirac masses, we selectively confine the chiral edge band around a single valley, enabling back-scattering-free propagation while imparting valley polarization. Our strategy not only addresses the valley depolarization issue but also introduces a unique functionality--valley multiplexing--allowing independent and arbitrary control over waves associated with different valley polarizations. We demonstrate our concept experimentally within hybrid topological photonic crystal systems composed of Chern and valley photonic crystals. Moreover, two key components for valley multiplexing are demonstrated: a valley (de-)multiplexer and a valley-locked waveguide crossing, facilitating non-interfering signal routing. Our results establish a novel interplay between the topological quantum Hall and valley Hall phases, offering a new framework for robust valley-based information processing.
title Chiral Valley Edge States
topic Optics
url https://arxiv.org/abs/2505.14383