Three-dimensional valley-locked waveguide transport enabled by phononic Weyl nodes

Mudi Wang; Qiyun Ma; Hao Wu; Yi Fang; Ruo Yang Zhang; Dongyang Wang; Hongwei Jia; Jing Hu; Zhengyou Liu; C. T. Chan

doi:10.1103/b2f7-7cs5

Three-dimensional valley-locked waveguide transport enabled by phononic Weyl nodes

Mudi Wang^*, Qiyun Ma, Hao Wu, Yi Fang, Ruo Yang Zhang, Dongyang Wang, Hongwei Jia, Jing Hu, Zhengyou Liu^*, C. T. Chan^*

^*Corresponding author for this work

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

Abstract

The flexible control of wave transport in three-dimensional (3D) space has long been a challenge. Here, we take advantage of the 3D linear dispersion of Weyl nodes and design a sandwiched valley-Hall crystal for robust acoustic waveguide transport. On the grounds of negligible intervalley scattering, such transport is valley locked and the waveguide shape can be altered in an arbitrary way. We experimentally validate such Weyl-node-based 3D topological transport by fabricating and characterizing a phononic crystal, and robust transmission for distinctive waveguide configurations has been observed. Our work introduces different avenues for implementing 3D valley-locked transport and offers a platform for topological device design.

Original language	English
Article number	144302
Pages (from-to)	1-6
Number of pages	6
Journal	Physical Review B
Volume	112
Issue number	14
DOIs	https://doi.org/10.1103/b2f7-7cs5
Publication status	Published - 3 Oct 2025

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©2025 American Physical Society

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title = "Three-dimensional valley-locked waveguide transport enabled by phononic Weyl nodes",

abstract = "The flexible control of wave transport in three-dimensional (3D) space has long been a challenge. Here, we take advantage of the 3D linear dispersion of Weyl nodes and design a sandwiched valley-Hall crystal for robust acoustic waveguide transport. On the grounds of negligible intervalley scattering, such transport is valley locked and the waveguide shape can be altered in an arbitrary way. We experimentally validate such Weyl-node-based 3D topological transport by fabricating and characterizing a phononic crystal, and robust transmission for distinctive waveguide configurations has been observed. Our work introduces different avenues for implementing 3D valley-locked transport and offers a platform for topological device design.",

author = "Mudi Wang and Qiyun Ma and Hao Wu and Yi Fang and Zhang, \{Ruo Yang\} and Dongyang Wang and Hongwei Jia and Jing Hu and Zhengyou Liu and Chan, \{C. T.\}",

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doi = "10.1103/b2f7-7cs5",

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T1 - Three-dimensional valley-locked waveguide transport enabled by phononic Weyl nodes

AU - Wang, Mudi

AU - Ma, Qiyun

AU - Wu, Hao

AU - Fang, Yi

AU - Zhang, Ruo Yang

AU - Wang, Dongyang

AU - Jia, Hongwei

AU - Hu, Jing

AU - Liu, Zhengyou

AU - Chan, C. T.

PY - 2025/10/3

Y1 - 2025/10/3

N2 - The flexible control of wave transport in three-dimensional (3D) space has long been a challenge. Here, we take advantage of the 3D linear dispersion of Weyl nodes and design a sandwiched valley-Hall crystal for robust acoustic waveguide transport. On the grounds of negligible intervalley scattering, such transport is valley locked and the waveguide shape can be altered in an arbitrary way. We experimentally validate such Weyl-node-based 3D topological transport by fabricating and characterizing a phononic crystal, and robust transmission for distinctive waveguide configurations has been observed. Our work introduces different avenues for implementing 3D valley-locked transport and offers a platform for topological device design.

AB - The flexible control of wave transport in three-dimensional (3D) space has long been a challenge. Here, we take advantage of the 3D linear dispersion of Weyl nodes and design a sandwiched valley-Hall crystal for robust acoustic waveguide transport. On the grounds of negligible intervalley scattering, such transport is valley locked and the waveguide shape can be altered in an arbitrary way. We experimentally validate such Weyl-node-based 3D topological transport by fabricating and characterizing a phononic crystal, and robust transmission for distinctive waveguide configurations has been observed. Our work introduces different avenues for implementing 3D valley-locked transport and offers a platform for topological device design.

UR - https://www.scopus.com/pages/publications/105020852753

U2 - 10.1103/b2f7-7cs5

DO - 10.1103/b2f7-7cs5

M3 - Journal Article

AN - SCOPUS:105020852753

SN - 2469-9950

VL - 112

SP - 1

EP - 6

JO - Physical Review B

JF - Physical Review B

IS - 14

M1 - 144302

ER -

Three-dimensional valley-locked waveguide transport enabled by phononic Weyl nodes

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