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Main Authors: Neuhaus, A., Gessler, P., Dreher, P., Janoschka, D., Rödl, A., Manten, M., Bauer, Th., Azhar, M., Frank, B., Davis, T. J., Giessen, H., Everschor-Sitte, K., Heringdorf, F. Meyer zu
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.26610
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author Neuhaus, A.
Gessler, P.
Dreher, P.
Janoschka, D.
Rödl, A.
Manten, M.
Bauer, Th.
Azhar, M.
Frank, B.
Davis, T. J.
Giessen, H.
Everschor-Sitte, K.
Heringdorf, F. Meyer zu
author_facet Neuhaus, A.
Gessler, P.
Dreher, P.
Janoschka, D.
Rödl, A.
Manten, M.
Bauer, Th.
Azhar, M.
Frank, B.
Davis, T. J.
Giessen, H.
Everschor-Sitte, K.
Heringdorf, F. Meyer zu
contents Topology describes properties of physical systems that remain constant under continuous deformations. For infinite vector waves, global topological invariants in position space are typically associated with periodic patterns. We demonstrate that even for aperiodic Helmholtz-decomposable wave fields, possessing only the wave's intrinsic periodicity, a topological invariant can be found in momentum space. This invariant, the linking number, represents a Berry phase. By utilizing electromagnetic and hydrodynamic surface waves, we confirm the robustness of the linking number against deformations, and experimentally observe discrete transitions between distinct topological sectors. The linking number captures the topology of vector wave fields across both continuous and discrete momentum spaces. Our work introduces a unified topological framework for vector wave fields, enabling their classification via a global invariant.
format Preprint
id arxiv_https___arxiv_org_abs_2604_26610
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Linking extended vector wave fields with momentum space topology
Neuhaus, A.
Gessler, P.
Dreher, P.
Janoschka, D.
Rödl, A.
Manten, M.
Bauer, Th.
Azhar, M.
Frank, B.
Davis, T. J.
Giessen, H.
Everschor-Sitte, K.
Heringdorf, F. Meyer zu
Optics
Topology describes properties of physical systems that remain constant under continuous deformations. For infinite vector waves, global topological invariants in position space are typically associated with periodic patterns. We demonstrate that even for aperiodic Helmholtz-decomposable wave fields, possessing only the wave's intrinsic periodicity, a topological invariant can be found in momentum space. This invariant, the linking number, represents a Berry phase. By utilizing electromagnetic and hydrodynamic surface waves, we confirm the robustness of the linking number against deformations, and experimentally observe discrete transitions between distinct topological sectors. The linking number captures the topology of vector wave fields across both continuous and discrete momentum spaces. Our work introduces a unified topological framework for vector wave fields, enabling their classification via a global invariant.
title Linking extended vector wave fields with momentum space topology
topic Optics
url https://arxiv.org/abs/2604.26610