Crystals (Dec 2022)

Topological Valley Transport of Elastic Waves Based on Periodic Triangular-Lattices

  • Zehuan Tang,
  • Jiachao Xu,
  • Bowei Wu,
  • Shuanghuizhi Li,
  • Fei Sun,
  • Tingfeng Ma,
  • Iren Kuznetsova,
  • Ilya Nedospasov,
  • Boyue Su,
  • Pengfei Kang

DOI
https://doi.org/10.3390/cryst13010067
Journal volume & issue
Vol. 13, no. 1
p. 67

Abstract

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Topological transports of elastic waves have attracted much attention because of their unique immunity to defects and backscattering-suppression ability. Periodic lattice structures are ideal carriers of elastic-wave transports due to their ability to manipulate elastic waves. Compared with honeycomb-lattice structures, the wave-guide-path designs of triangular-lattice structures have higher flexibility. In this paper, topological transports of elastic waves in the periodic triangular-lattice structure are explored. It is shown that differences between intra-coupling and inter-coupling radii can cause the destruction of the effective spatial inversion symmetry, which gives rise to the valley Hall phase transition and the forming of topological edge states. Utilizing valley Hall effect, topological transports of elastic waves traveling along linear and Z-shaped waveguides are realized with low scattering and immunity to defects. On this basis, the path-selection function of transports of elastic waves in periodic triangular-lattice structures is obtained. Topological valley Hall edge states of elastic waves in periodic triangular-lattice structures have a good application prospects in elastic-wave manipulations and communications.

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