Nature Communications (Mar 2024)

Wandering principal optical axes in van der Waals triclinic materials

  • Georgy A. Ermolaev,
  • Kirill V. Voronin,
  • Adilet N. Toksumakov,
  • Dmitriy V. Grudinin,
  • Ilia M. Fradkin,
  • Arslan Mazitov,
  • Aleksandr S. Slavich,
  • Mikhail K. Tatmyshevskiy,
  • Dmitry I. Yakubovsky,
  • Valentin R. Solovey,
  • Roman V. Kirtaev,
  • Sergey M. Novikov,
  • Elena S. Zhukova,
  • Ivan Kruglov,
  • Andrey A. Vyshnevyy,
  • Denis G. Baranov,
  • Davit A. Ghazaryan,
  • Aleksey V. Arsenin,
  • Luis Martin-Moreno,
  • Valentyn S. Volkov,
  • Kostya S. Novoselov

DOI
https://doi.org/10.1038/s41467-024-45266-3
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 8

Abstract

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Abstract Nature is abundant in material platforms with anisotropic permittivities arising from symmetry reduction that feature a variety of extraordinary optical effects. Principal optical axes are essential characteristics for these effects that define light-matter interaction. Their orientation – an orthogonal Cartesian basis that diagonalizes the permittivity tensor, is often assumed stationary. Here, we show that the low-symmetry triclinic crystalline structure of van der Waals rhenium disulfide and rhenium diselenide is characterized by wandering principal optical axes in the space-wavelength domain with above π/2 degree of rotation for in-plane components. In turn, this leads to wavelength-switchable propagation directions of their waveguide modes. The physical origin of wandering principal optical axes is explained using a multi-exciton phenomenological model and ab initio calculations. We envision that the wandering principal optical axes of the investigated low-symmetry triclinic van der Waals crystals offer a platform for unexplored anisotropic phenomena and nanophotonic applications.