Nature Communications (Aug 2024)

Axion topology in photonic crystal domain walls

  • Chiara Devescovi,
  • Antonio Morales-Pérez,
  • Yoonseok Hwang,
  • Mikel García-Díez,
  • Iñigo Robredo,
  • Juan Luis Mañes,
  • Barry Bradlyn,
  • Aitzol García-Etxarri,
  • Maia G. Vergniory

DOI
https://doi.org/10.1038/s41467-024-50766-3
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 12

Abstract

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Abstract Axion insulators are 3D magnetic topological insulators supporting hinge states and quantized magnetoelectric effects, recently proposed for detecting dark-matter axionic particles via their axionic excitations. Beyond theoretical interest, obtaining a photonic counterpart of axion insulators offers potential for advancing magnetically-tunable photonic devices and axion haloscopes based on axion-photon conversion. This work proposes an axionic 3D phase within a photonic setup. By building inversion-symmetric domain-walls in gyrotropic photonic crystals, we bind chiral modes on inversion-related hinges, ultimately leading to the realization of an axionic channel of light. These states propagate embedded in a 3D structure, thus protected from radiation in the continuum. Employing a small external gyromagnetic bias, we transition across different axionic mode configurations, enabling effective topological switching of chiral photonic fibers. While demonstrating the possibility of realizing axion photonic crystals within state-of-the-art gyrotropic setups, we propose a general scheme for rendering axion topology at domain walls of Weyl semimetals.