Guiding robust valley-dependent edge states by surface acoustic waves

Zhen Wang; Fu Kang Liu; Si Yuan Yu; Shi Ling Yan; Ming Hui Lu; Yun Jing; Yan Feng Chen

doi:10.1063/1.5066034

Guiding robust valley-dependent edge states by surface acoustic waves

Zhen Wang, Fu Kang Liu, Si Yuan Yu, Shi Ling Yan, Ming Hui Lu, Yun Jing, Yan Feng Chen

Graduate Program in Acoustics

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

27 Scopus citations

Abstract

Recently, the concept of valley pseudospin, labeling quantum states of energy extrema in momentum space, has attracted enormous attention because of its potential as a new type of information carrier. Here, we present surface acoustic wave (SAW) waveguides which utilize and transport valley pseudospins in two-dimensional SAW phononic crystals. In addition to a direct visualization of the valley-dependent modes excited from the corresponding chiral sources, the backscattering suppression of SAW valley-dependent edge modes transport is observed in sharply curved interfaces. By means of band structure engineering, elastic wave energy in the SAW waveguides can be transported with remarkable robustness, which is very promising for new generations of integrated solid-state phononic circuits with great versatility.

Original language	English (US)
Article number	044502
Journal	Journal of Applied Physics
Volume	125
Issue number	4
DOIs	https://doi.org/10.1063/1.5066034
State	Published - Jan 28 2019

All Science Journal Classification (ASJC) codes

General Physics and Astronomy

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10.1063/1.5066034

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title = "Guiding robust valley-dependent edge states by surface acoustic waves",

abstract = "Recently, the concept of valley pseudospin, labeling quantum states of energy extrema in momentum space, has attracted enormous attention because of its potential as a new type of information carrier. Here, we present surface acoustic wave (SAW) waveguides which utilize and transport valley pseudospins in two-dimensional SAW phononic crystals. In addition to a direct visualization of the valley-dependent modes excited from the corresponding chiral sources, the backscattering suppression of SAW valley-dependent edge modes transport is observed in sharply curved interfaces. By means of band structure engineering, elastic wave energy in the SAW waveguides can be transported with remarkable robustness, which is very promising for new generations of integrated solid-state phononic circuits with great versatility.",

author = "Zhen Wang and Liu, {Fu Kang} and Yu, {Si Yuan} and Yan, {Shi Ling} and Lu, {Ming Hui} and Yun Jing and Chen, {Yan Feng}",

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T1 - Guiding robust valley-dependent edge states by surface acoustic waves

AU - Wang, Zhen

AU - Liu, Fu Kang

AU - Yu, Si Yuan

AU - Yan, Shi Ling

AU - Lu, Ming Hui

AU - Jing, Yun

AU - Chen, Yan Feng

PY - 2019/1/28

Y1 - 2019/1/28

N2 - Recently, the concept of valley pseudospin, labeling quantum states of energy extrema in momentum space, has attracted enormous attention because of its potential as a new type of information carrier. Here, we present surface acoustic wave (SAW) waveguides which utilize and transport valley pseudospins in two-dimensional SAW phononic crystals. In addition to a direct visualization of the valley-dependent modes excited from the corresponding chiral sources, the backscattering suppression of SAW valley-dependent edge modes transport is observed in sharply curved interfaces. By means of band structure engineering, elastic wave energy in the SAW waveguides can be transported with remarkable robustness, which is very promising for new generations of integrated solid-state phononic circuits with great versatility.

AB - Recently, the concept of valley pseudospin, labeling quantum states of energy extrema in momentum space, has attracted enormous attention because of its potential as a new type of information carrier. Here, we present surface acoustic wave (SAW) waveguides which utilize and transport valley pseudospins in two-dimensional SAW phononic crystals. In addition to a direct visualization of the valley-dependent modes excited from the corresponding chiral sources, the backscattering suppression of SAW valley-dependent edge modes transport is observed in sharply curved interfaces. By means of band structure engineering, elastic wave energy in the SAW waveguides can be transported with remarkable robustness, which is very promising for new generations of integrated solid-state phononic circuits with great versatility.

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Guiding robust valley-dependent edge states by surface acoustic waves

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