Controllably asymmetric beam splitting via gap-induced diffraction channel transition in dual-layer binary metagratings

Controllably asymmetric beam splitting via gap-induced diffraction channel transition in dual-layer binary metagratings

In this work, we designed and studied a feasible dual-layer binary metagrating, which can realize controllable asymmetric transmission and beam splitting with nearly perfect performance. Owing to ingenious geometry configuration, only one meta-atom is required to design for the metagrating system. B...

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Veröffentlicht in:Frontiers of physics 2020-10, Vol.15 (5), p.52502, Article 52502
Hauptverfasser: Fu, Yang-Yang, Tao, Jia-Qi, Song, Ai-Ling, Liu, You-Wen, Xu, Ya-Dong
Format: Artikel
Sprache:eng
Schlagworte:
acoustic metagrating
Acoustics
Astronomy
Astrophysics and Cosmology
asymmetric transmission
Asymmetry
Atomic
Beam splitters
beam splitting
binary design
Condensed Matter Physics
Controllability
Design
Efficiency
Frequencies
Incident waves
Molecular
Noise control
Noise propagation
Optical and Plasma Physics
Particle and Nuclear Physics
Physics
Physics and Astronomy
Propagation
Research Article
Splitting
Wave diffraction
Wave fronts
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Zusammenfassung:In this work, we designed and studied a feasible dual-layer binary metagrating, which can realize controllable asymmetric transmission and beam splitting with nearly perfect performance. Owing to ingenious geometry configuration, only one meta-atom is required to design for the metagrating system. By simply controlling air gap between dual-layer metagratings, high-efficiency beam splitting can be well switched from asymmetric transmission to symmetric transmission. The working principle lies on gap-induced diffraction channel transition for incident waves from opposite directions. The asymmetric/symmetric transmission can work in a certain frequency band and a wide incident range. Compared with previous methods using acoustic metasurfaces, our approach has the advantages of simple design and tunable property and shows promise for applications in wavefront manipulation, noise control and one-way propagation.
ISSN:2095-0462
2095-0470
DOI:10.1007/s11467-020-0968-2