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Main Authors: Zeng, Xinji, Wang, Jinwen, Chen, Yun, Liu, Guang, Guo, Zhenyu, Zhou, Yongkun, Yang, Xin, Wang, Chengyuan, Wei, Dong, Chen, Haixia, Shen, Yijie, Forbes, Andrew, Gao, Hong
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.21424
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author Zeng, Xinji
Wang, Jinwen
Chen, Yun
Liu, Guang
Guo, Zhenyu
Zhou, Yongkun
Yang, Xin
Wang, Chengyuan
Wei, Dong
Chen, Haixia
Shen, Yijie
Forbes, Andrew
Gao, Hong
author_facet Zeng, Xinji
Wang, Jinwen
Chen, Yun
Liu, Guang
Guo, Zhenyu
Zhou, Yongkun
Yang, Xin
Wang, Chengyuan
Wei, Dong
Chen, Haixia
Shen, Yijie
Forbes, Andrew
Gao, Hong
contents Hopfions, as three-dimensional topologically nontrivial structures described by poloidal and toroidal winding numbers, hold promise as robust information carriers in spintronics, functional materials, and optical communications. Although they have been experimentally realized in various physical systems, such realizations have been restricted to low orders, with the winding numbers lacking tunability. Here, using optical fields as our platform, we outline how to make tunable hopfions in any order with any winding number. We use tailored superpositions of Laguerre-Gaussian modes in free-space as our construction, achieving effective control for arbitrary-order poloidal and toroidal winding numbers, which we demonstrate up to orders 5 and 3, respectively, for a new state-of-the-art. The resulting torus-knot structures are visualized experimentally via polarization filaments, confirming the designed topological textures. Our work reports an exotic optical topologies observed in free space, provides a systematic route hopfions of any order, with implications for topological photonics, optical communications, and analogies in magnetic and condensed-matter systems.
format Preprint
id arxiv_https___arxiv_org_abs_2604_21424
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Optical hopfions with arbitrary two winding numbers
Zeng, Xinji
Wang, Jinwen
Chen, Yun
Liu, Guang
Guo, Zhenyu
Zhou, Yongkun
Yang, Xin
Wang, Chengyuan
Wei, Dong
Chen, Haixia
Shen, Yijie
Forbes, Andrew
Gao, Hong
Optics
Hopfions, as three-dimensional topologically nontrivial structures described by poloidal and toroidal winding numbers, hold promise as robust information carriers in spintronics, functional materials, and optical communications. Although they have been experimentally realized in various physical systems, such realizations have been restricted to low orders, with the winding numbers lacking tunability. Here, using optical fields as our platform, we outline how to make tunable hopfions in any order with any winding number. We use tailored superpositions of Laguerre-Gaussian modes in free-space as our construction, achieving effective control for arbitrary-order poloidal and toroidal winding numbers, which we demonstrate up to orders 5 and 3, respectively, for a new state-of-the-art. The resulting torus-knot structures are visualized experimentally via polarization filaments, confirming the designed topological textures. Our work reports an exotic optical topologies observed in free space, provides a systematic route hopfions of any order, with implications for topological photonics, optical communications, and analogies in magnetic and condensed-matter systems.
title Optical hopfions with arbitrary two winding numbers
topic Optics
url https://arxiv.org/abs/2604.21424