Communications Physics (Jan 2024)

Non-orthogonal cavity modes near exceptional points in the far field

  • Jingnan Yang,
  • Shushu Shi,
  • Sai Yan,
  • Rui Zhu,
  • Xiaoming Zhao,
  • Yi Qin,
  • Bowen Fu,
  • Xiqing Chen,
  • Hancong Li,
  • Zhanchun Zuo,
  • Kuijuan Jin,
  • Qihuang Gong,
  • Xiulai Xu

DOI
https://doi.org/10.1038/s42005-023-01508-2
Journal volume & issue
Vol. 7, no. 1
pp. 1 – 8

Abstract

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Abstract Non-orthogonal eigenstates are a fundamental feature of non-Hermitian systems and are accompanied by the emergence of nontrivial features. However, the platforms to explore non-Hermitian mode couplings mainly measure near-field effects, and the far-field behaviours remain mostly unexplored. Here, we study how a microcavity with non-Hermitian mode coupling exhibits eigenstate non-orthogonality by investigating the spatial field and the far-field polarization of cavity modes. The non-Hermiticity arises from asymmetric backscattering, which is controlled by integrating two scatterers of different size and location into a microdisk. We observe that the spatial field overlap of two modes increases abruptly to its maximum value, whilst different far-field elliptical polarizations of two modes coalesce when approaching an exceptional point. We demonstrate such features experimentally by measuring the far-field polarization from the fabricated microdisks. Our work reveals the non-orthogonality in the far-field degree of freedom, and the integrability of the microdisks paves a way to integrate more non-Hermitian optical properties into nanophotonic systems.