Broadband large-scale acoustic topological waveguides

Yafeng Chen; Xueyun Wen; Yan Lu; Zhihao Lan; Lei Fan; Harold S. Park; Zhongming Gu; Jie Zhu; Zhongqing Su

doi:10.1016/j.compstruct.2024.118669

Broadband large-scale acoustic topological waveguides

Yafeng Chen, Xueyun Wen, Yan Lu, Zhihao Lan, Lei Fan, Harold S. Park, Zhongming Gu, Jie Zhu, Zhongqing Su

Research output: Journal article publication › Journal article › Academic research › peer-review

2 Citations (Scopus)

Abstract

The acoustic topological waveguide (ATW) hosting topologically protected waveguide modes provides a unique opportunity for achieving large-scale sound transport with robustness. However, prevailing ATWs are typically designed by forward-designed sonic crystals (SCs) based on physical intuitions, unavoidably leading to restricted bandwidths. Here, using the inverse-designed SCs with maximized topological bandgaps, we construct broadband ATWs based on both the quantum spin Hall effect and the quantum valley Hall effect. Broadband large-scale transportation, spin-locked one-way transportation, and the squeezing effect of acoustic waves are demonstrated. This study ushers a new path for designing topological devices with broadband performance for large-scale acoustic wave transportation.

Original language	English
Article number	118669
Journal	Composite Structures
Volume	352
DOIs	https://doi.org/10.1016/j.compstruct.2024.118669
Publication status	Published - 15 Jan 2025

Keywords

Inverse design
Sonic crystals
Topological insulator
Topological waveguide

ASJC Scopus subject areas

Ceramics and Composites
Civil and Structural Engineering

More information

10.1016/j.compstruct.2024.118669

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title = "Broadband large-scale acoustic topological waveguides",

abstract = "The acoustic topological waveguide (ATW) hosting topologically protected waveguide modes provides a unique opportunity for achieving large-scale sound transport with robustness. However, prevailing ATWs are typically designed by forward-designed sonic crystals (SCs) based on physical intuitions, unavoidably leading to restricted bandwidths. Here, using the inverse-designed SCs with maximized topological bandgaps, we construct broadband ATWs based on both the quantum spin Hall effect and the quantum valley Hall effect. Broadband large-scale transportation, spin-locked one-way transportation, and the squeezing effect of acoustic waves are demonstrated. This study ushers a new path for designing topological devices with broadband performance for large-scale acoustic wave transportation.",

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AU - Chen, Yafeng

AU - Wen, Xueyun

AU - Lu, Yan

AU - Lan, Zhihao

AU - Fan, Lei

AU - Park, Harold S.

AU - Gu, Zhongming

AU - Zhu, Jie

AU - Su, Zhongqing

PY - 2025/1/15

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AB - The acoustic topological waveguide (ATW) hosting topologically protected waveguide modes provides a unique opportunity for achieving large-scale sound transport with robustness. However, prevailing ATWs are typically designed by forward-designed sonic crystals (SCs) based on physical intuitions, unavoidably leading to restricted bandwidths. Here, using the inverse-designed SCs with maximized topological bandgaps, we construct broadband ATWs based on both the quantum spin Hall effect and the quantum valley Hall effect. Broadband large-scale transportation, spin-locked one-way transportation, and the squeezing effect of acoustic waves are demonstrated. This study ushers a new path for designing topological devices with broadband performance for large-scale acoustic wave transportation.

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Broadband large-scale acoustic topological waveguides

Abstract

Keywords

ASJC Scopus subject areas

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