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- Title
Designing transparent piezoelectric metasurfaces for adaptive optics.
- Authors
Qiao, Liao; Gao, Xiangyu; Ren, Kaile; Qiu, Chaorui; Liu, Jinfeng; Jin, Haonan; Dong, Shuxiang; Xu, Zhuo; Li, Fei
- Abstract
Simultaneously generating various motion modes with high strains in piezoelectric devices is highly desired for high-technology fields to achieve multi-functionalities. However, traditional approach for designing multi-degrees-of-freedom systems is to bond together several multilayer piezoelectric stacks, which generally leads to cumbersome and complicated structures. Here, we proposed a transparent piezo metasurface to achieve various types of strains in a wide frequency range. As an example, we designed a ten-unit piezo metasurface, which can produce high strains (ε3 = 0.76%), and generate linear motions along X-, Y- and Z-axis, rotary motions around X-, Y- and Z-axis as well as coupled modes. An adaptive lens based on the proposed piezo metasurface was demonstrated. It can realize a wide range of focal length (35.82 cm ~ ∞) and effective image stabilization with relatively large displacements (5.05 μm along Y-axis) and tilt angles (44.02′ around Y-axis). This research may benefit the miniaturization and integration of multi-degrees-of-freedom systems. Most multi-degrees-of-freedom systems are composed of several piezoelectric stacks, leading to cumbersome and complicated structures. Here, the authors propose a piezo metasurface to achieve various types of high strains in a wide frequency range.
- Subjects
IMAGE stabilization; PIEZOELECTRIC devices; FOCAL length; ADAPTIVE optics
- Publication
Nature Communications, 2024, Vol 15, Issue 1, p1
- ISSN
2041-1723
- Publication type
Article
- DOI
10.1038/s41467-024-45088-3