Dynamic Acoustic Beamshaping with Coupling‐Immune Moiré Metasurfaces

Moiré effects arising from mutually twisted metasurfaces have showcased remarkable wave manipulation capabilities, unveiling tantalizing emerging phenomena such as acoustic moiré flat bands and topological phase transitions. However, the pursuit of strong near‐field coupling in layers has necessitat...

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Veröffentlicht in:	Advanced materials (Weinheim) 2024-06, Vol.36 (24), p.e2313004-n/a
Hauptverfasser:	Zhou, Hong‐Tao, Li, Chen‐Yang, Zhu, Jia‐Hui, Hu, Chuanjie, Wang, Yan‐Feng, Wang, Yue‐Sheng, Qiu, Cheng‐Wei
Format:	Artikel
Sprache:	eng
Schlagworte:	Acoustics Coupling coupling‐immune moiré effects Interlayers Metasurfaces Moire effects multi‐channel vortex emission Phase transitions tunable beam scanning twisted acoustic metasurfaces Underwater acoustics Underwater communication
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creator	Zhou, Hong‐Tao Li, Chen‐Yang Zhu, Jia‐Hui Hu, Chuanjie Wang, Yan‐Feng Wang, Yue‐Sheng Qiu, Cheng‐Wei
description	Moiré effects arising from mutually twisted metasurfaces have showcased remarkable wave manipulation capabilities, unveiling tantalizing emerging phenomena such as acoustic moiré flat bands and topological phase transitions. However, the pursuit of strong near‐field coupling in layers has necessitated acoustic moiré metasurfaces to be tightly stacked at narrow distances in the subwavelength range. Here, moiré effects beyond near‐field interlayer coupling in acoustics are reported and the concept of coupling‐immune moiré metasurfaces is proposed. Remote acoustic moiré effects decoupled from the interlayer distance are theoretically, numerically, and experimentally demonstrated. Tunable out‐of‐plane acoustic beam scanning is successfully achieved by dynamically controlling twist angles. The engineered coupling‐immune properties are further extended to multilayered acoustic moiré metasurfaces and manipulation of acoustic vortices. Good robustness against external disturbances is also observed for the fabricated coupling‐immune acoustic moiré metasurfaces. The presented work unlocks the potential of twisted moiré devices for out‐of‐plane acoustic beam shaping, enabling practical applications in remote dynamic detection, and multiplexed underwater acoustic communication. Coupling‐immune acoustic moiré metasurfaces are proposed by leveraging the interlayer coupling from propagating waves. Remote acoustic moiré effects are theoretically and experimentally validated to be decoupled from the interlayer distance. The dynamic shaping of acoustic beams and vortices is successfully achieved, facilitating twisted moiré devices of practical applications in remote dynamic detection and multiplexed underwater acoustic communication.
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However, the pursuit of strong near‐field coupling in layers has necessitated acoustic moiré metasurfaces to be tightly stacked at narrow distances in the subwavelength range. Here, moiré effects beyond near‐field interlayer coupling in acoustics are reported and the concept of coupling‐immune moiré metasurfaces is proposed. Remote acoustic moiré effects decoupled from the interlayer distance are theoretically, numerically, and experimentally demonstrated. Tunable out‐of‐plane acoustic beam scanning is successfully achieved by dynamically controlling twist angles. The engineered coupling‐immune properties are further extended to multilayered acoustic moiré metasurfaces and manipulation of acoustic vortices. Good robustness against external disturbances is also observed for the fabricated coupling‐immune acoustic moiré metasurfaces. The presented work unlocks the potential of twisted moiré devices for out‐of‐plane acoustic beam shaping, enabling practical applications in remote dynamic detection, and multiplexed underwater acoustic communication. Coupling‐immune acoustic moiré metasurfaces are proposed by leveraging the interlayer coupling from propagating waves. Remote acoustic moiré effects are theoretically and experimentally validated to be decoupled from the interlayer distance. 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subjects	Acoustics Coupling coupling‐immune moiré effects Interlayers Metasurfaces Moire effects multi‐channel vortex emission Phase transitions tunable beam scanning twisted acoustic metasurfaces Underwater acoustics Underwater communication
title	Dynamic Acoustic Beamshaping with Coupling‐Immune Moiré Metasurfaces
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