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Topological water-wave structures manipulating particles

Bo Wang, Zhiyuan Che, Cheng Cheng, Caili Tong, Lei Shi (), Yijie Shen (), Konstantin Y. Bliokh () and Jian Zi ()
Additional contact information
Bo Wang: Fudan University
Zhiyuan Che: Fudan University
Cheng Cheng: Fudan University
Caili Tong: Henan University
Lei Shi: Fudan University
Yijie Shen: Nanyang Technological University
Konstantin Y. Bliokh: Donostia International Physics Center (DIPC)
Jian Zi: Fudan University

Nature, 2025, vol. 638, issue 8050, 394-400

Abstract: Abstract Topological wave structures, such as vortices1–6, polarization textures7–11 and skyrmions12–19, appear in various quantum and classical wave fields, including optics and acoustics. In particular, optical vortices have found numerous applications20,21, ranging from quantum information to astrophysics. Furthermore, both optical and acoustic structured waves are crucial in the manipulation of small particles22–25, from atoms to macroscopic biological objects. Recently, there has been a surge of interest in structured water surface waves, which can be notable analogues of quantum, optical and acoustic wave systems26–29. However, topological water-wave forms, especially their ability to manipulate particles, have not yet been demonstrated. Here we describe the controllable generation of topological structures, namely wave vortices, skyrmions and polarization Möbius strips, in gravity water waves. Most importantly, we demonstrate the efficient manipulation of subwavelength and wavelength-order floating particles with topologically structured water waves. This includes trapping the particles in the high-intensity field zones and controlling their orbital and spinning motion due to the orbital and spin angular momenta of the water waves. Our results reveal the water-wave counterpart of optical and acoustic manipulation, which paves the way for applications in hydrodynamics and microfluidics.

Date: 2025
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DOI: 10.1038/s41586-024-08384-y

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