Pseudomagnetic Fields Enabled Manipulation of On-Chip Elastic Waves

Mou Yan; Weiyin Deng; Xueqin Huang; Ying Wu; Yating Yang; Jiuyang Lu; Feng Li; Zhengyou Liu

doi:10.1103/PhysRevLett.127.136401

Pseudomagnetic Fields Enabled Manipulation of On-Chip Elastic Waves

Mou Yan, Weiyin Deng, Xueqin Huang, Ying Wu, Yating Yang, Jiuyang Lu, Feng Li, Zhengyou Liu

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

35 Citations (Scopus)

Abstract

The physical realization of pseudomagnetic fields (PMFs) is an engaging frontier of research. As in graphene, elastic PMF can be realized by the structural modulations of Dirac materials. We show that, in the presence of PMFs, the conical dispersions split into elastic Landau levels, and the elastic modes robustly propagate along the edges, similar to the quantum Hall edge transports. In particular, we reveal unique elastic snake states in an on-chip heterostructure with two opposite PMFs. The flexibility in the micromanufacture of silicon chips and the low loss of elastic waves provide an unprecedented opportunity to demonstrate various fascinating topological transports of the edge states under PMFs. These properties open new possibilities for designing functional elastic wave devices in miniature and compact scales.

Original language	English
Article number	136401
Journal	Physical Review Letters
Volume	127
Issue number	13
DOIs	https://doi.org/10.1103/PhysRevLett.127.136401
Publication status	Published - 24 Sept 2021
Externally published	Yes

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title = "Pseudomagnetic Fields Enabled Manipulation of On-Chip Elastic Waves",

abstract = "The physical realization of pseudomagnetic fields (PMFs) is an engaging frontier of research. As in graphene, elastic PMF can be realized by the structural modulations of Dirac materials. We show that, in the presence of PMFs, the conical dispersions split into elastic Landau levels, and the elastic modes robustly propagate along the edges, similar to the quantum Hall edge transports. In particular, we reveal unique elastic snake states in an on-chip heterostructure with two opposite PMFs. The flexibility in the micromanufacture of silicon chips and the low loss of elastic waves provide an unprecedented opportunity to demonstrate various fascinating topological transports of the edge states under PMFs. These properties open new possibilities for designing functional elastic wave devices in miniature and compact scales.",

author = "Mou Yan and Weiyin Deng and Xueqin Huang and Ying Wu and Yating Yang and Jiuyang Lu and Feng Li and Zhengyou Liu",

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AU - Yan, Mou

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AU - Yang, Yating

AU - Lu, Jiuyang

AU - Li, Feng

AU - Liu, Zhengyou

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N2 - The physical realization of pseudomagnetic fields (PMFs) is an engaging frontier of research. As in graphene, elastic PMF can be realized by the structural modulations of Dirac materials. We show that, in the presence of PMFs, the conical dispersions split into elastic Landau levels, and the elastic modes robustly propagate along the edges, similar to the quantum Hall edge transports. In particular, we reveal unique elastic snake states in an on-chip heterostructure with two opposite PMFs. The flexibility in the micromanufacture of silicon chips and the low loss of elastic waves provide an unprecedented opportunity to demonstrate various fascinating topological transports of the edge states under PMFs. These properties open new possibilities for designing functional elastic wave devices in miniature and compact scales.

AB - The physical realization of pseudomagnetic fields (PMFs) is an engaging frontier of research. As in graphene, elastic PMF can be realized by the structural modulations of Dirac materials. We show that, in the presence of PMFs, the conical dispersions split into elastic Landau levels, and the elastic modes robustly propagate along the edges, similar to the quantum Hall edge transports. In particular, we reveal unique elastic snake states in an on-chip heterostructure with two opposite PMFs. The flexibility in the micromanufacture of silicon chips and the low loss of elastic waves provide an unprecedented opportunity to demonstrate various fascinating topological transports of the edge states under PMFs. These properties open new possibilities for designing functional elastic wave devices in miniature and compact scales.

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Pseudomagnetic Fields Enabled Manipulation of On-Chip Elastic Waves

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