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      Structure-Composition Correspondence in Crystalline Metamaterials for Acoustic Valley-Hall Effect and Unidirectional Sound Guiding

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          Abstract

          Recently, the domain of topological insulators in condensed matter physics has been teeming with intriguing and very exciting discoveries. Notably, the capacity of guiding currents towards specific directions according to the spin of the travelling electrons has a great potential for electronic devices. This new phenomenon has been transposed to the classical domain in electromagnetics and acoustics, unveiling the pseudo-spin locking of guided waves. However, these macroscopic analogues are photonic/phononic crystals which are intrinsically wavelength scaled. In this work, we realize a genuine acoustic analogue of the valley-Hall effect in the audible regime using a lattice of soda cans. The crystalline description of this very simple metamaterial allows us to demonstrate experimentally the unidirectional excitation of sound guided at a scale much smaller than the wavelength of operation. These results not only open the tantalizing valley-topological phenomena to the audible regime but also allow to envision compact applications for acoustic manipulation.

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          Author and article information

          Journal
          21 April 2020
          Article
          10.1209/0295-5075/129/44001
          2004.09886
          f750ca5e-5556-4613-8e09-81b3a2684a5a

          http://arxiv.org/licenses/nonexclusive-distrib/1.0/

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          Custom metadata
          Simon Yves et al 2020 EPL 129 44001
          physics.app-ph

          Technical & Applied physics
          Technical & Applied physics

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