Twist-on-Twist Moiré Elastic Metasurfaces

Menghan Li; Kuan He; Zhiwen Ren; Li Qun Chen; Hao Wen Dong; Chenglin Han; Tianzhi Yang; Cheng Wei Qiu

doi:10.1103/qw7j-fj7b

Twist-on-Twist Moiré Elastic Metasurfaces

Menghan Li
, Kuan He
, Zhiwen Ren
, Li Qun Chen
, Hao Wen Dong^*
, Chenglin Han
, Tianzhi Yang^*
, Cheng Wei Qiu^*

^*Corresponding author for this work

Northeastern University China
Beijing Institute of Technology
Harbin Institute of Technology
National University of Singapore

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

3 Citations (Scopus)

Abstract

The concepts of twistronics and magic angle have been widely applied beyond electrons, powering up new advancements in optics, acoustics, and heat transport. However, achieving a unidirectional or all-direction "magic angle"remains an established yet unresolved challenge in twisted bilayer metasurfaces across various disciplines. Our work proposes and validates a "twist-on-twist"paradigm to realizing unidirectional propagation and robust magic angle at arbitrary directions of the elastic out-of-plane wave. Our elastic metasurface not only exhibits a twisted configuration between the stacked bilayer but also significantly enhances out-of-plane symmetry breaking by further twisting meta-atoms in one constituent layer. Our twist-on-twist method unleashes versatile potentials of twisted thin composite materials to control the extreme propagation of topological elastic waves and even opens up new possibilities for photonic, phononic, and thermal moiré metamaterials.

Original language	English
Article number	126301
Journal	Physical Review Letters
Volume	135
Issue number	12
DOIs	https://doi.org/10.1103/qw7j-fj7b
Publication status	Published - 19 Sept 2025
Externally published	Yes

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title = "Twist-on-Twist Moir{\'e} Elastic Metasurfaces",

abstract = "The concepts of twistronics and magic angle have been widely applied beyond electrons, powering up new advancements in optics, acoustics, and heat transport. However, achieving a unidirectional or all-direction {"}magic angle{"}remains an established yet unresolved challenge in twisted bilayer metasurfaces across various disciplines. Our work proposes and validates a {"}twist-on-twist{"}paradigm to realizing unidirectional propagation and robust magic angle at arbitrary directions of the elastic out-of-plane wave. Our elastic metasurface not only exhibits a twisted configuration between the stacked bilayer but also significantly enhances out-of-plane symmetry breaking by further twisting meta-atoms in one constituent layer. Our twist-on-twist method unleashes versatile potentials of twisted thin composite materials to control the extreme propagation of topological elastic waves and even opens up new possibilities for photonic, phononic, and thermal moir{\'e} metamaterials.",

author = "Menghan Li and Kuan He and Zhiwen Ren and Chen, \{Li Qun\} and Dong, \{Hao Wen\} and Chenglin Han and Tianzhi Yang and Qiu, \{Cheng Wei\}",

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doi = "10.1103/qw7j-fj7b",

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T1 - Twist-on-Twist Moiré Elastic Metasurfaces

AU - Li, Menghan

AU - He, Kuan

AU - Ren, Zhiwen

AU - Chen, Li Qun

AU - Dong, Hao Wen

AU - Han, Chenglin

AU - Yang, Tianzhi

AU - Qiu, Cheng Wei

PY - 2025/9/19

Y1 - 2025/9/19

N2 - The concepts of twistronics and magic angle have been widely applied beyond electrons, powering up new advancements in optics, acoustics, and heat transport. However, achieving a unidirectional or all-direction "magic angle"remains an established yet unresolved challenge in twisted bilayer metasurfaces across various disciplines. Our work proposes and validates a "twist-on-twist"paradigm to realizing unidirectional propagation and robust magic angle at arbitrary directions of the elastic out-of-plane wave. Our elastic metasurface not only exhibits a twisted configuration between the stacked bilayer but also significantly enhances out-of-plane symmetry breaking by further twisting meta-atoms in one constituent layer. Our twist-on-twist method unleashes versatile potentials of twisted thin composite materials to control the extreme propagation of topological elastic waves and even opens up new possibilities for photonic, phononic, and thermal moiré metamaterials.

AB - The concepts of twistronics and magic angle have been widely applied beyond electrons, powering up new advancements in optics, acoustics, and heat transport. However, achieving a unidirectional or all-direction "magic angle"remains an established yet unresolved challenge in twisted bilayer metasurfaces across various disciplines. Our work proposes and validates a "twist-on-twist"paradigm to realizing unidirectional propagation and robust magic angle at arbitrary directions of the elastic out-of-plane wave. Our elastic metasurface not only exhibits a twisted configuration between the stacked bilayer but also significantly enhances out-of-plane symmetry breaking by further twisting meta-atoms in one constituent layer. Our twist-on-twist method unleashes versatile potentials of twisted thin composite materials to control the extreme propagation of topological elastic waves and even opens up new possibilities for photonic, phononic, and thermal moiré metamaterials.

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JO - Physical Review Letters

JF - Physical Review Letters

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ER -

Twist-on-Twist Moiré Elastic Metasurfaces

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