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Acoustic Metagrating Holograms.

Hong-Yu ZouYong GeKe-Qi ZhaoYu-Jing LuQiao-Rui SiShou-Qi YuanHongsheng ChenHong-Xiang SunYihao YangBaile Zhang
Published in: Advanced materials (Deerfield Beach, Fla.) (2024)
Metasurface holograms represent a common category of metasurface devices that utilize in-plane phase gradients to shape wavefronts, forming holographic images through the application of the generalized Snell's law (GSL). While conventional metasurfaces focus solely on phase gradients, metagratings, which incorporate higher-order wave diffraction, further expand the GSL's generality. Recent advances in certain acoustic metagratings demonstrate an updated GSL extension capable of reversing anomalous transmission and reflection, whose reversal is characterized by the parity of the number of wave propagation trips through the metagrating. However, the current extension of GSL remains limited to 1D metagratings, unable to access 2D holographic images in 3D spaces. Here, the GSL extension to 2D metagratings for manipulating waves within 3D spaces is investigated. Through this analysis, a series of acoustic metagrating holograms is experimentally demonstrated. These holographic images exhibit the unique ability to switch between transmission and reflection types independently. This study introduces an additional dimension to modern holography design and metasurface wavefront manipulation.
Keyphrases
  • deep learning
  • convolutional neural network
  • optical coherence tomography
  • high speed