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Experimental Realization of Weyl Exceptional Rings in a Synthetic Three-Dimensional Non-Hermitian Phononic Crystal

Jingjing Liu, Zhengwei Li, Ze‐Guo Chen, Weiyuan Tang, An Chen, Bin Liang, Guancong Ma, Jian‐Chun Cheng

2022Physical Review Letters106 citationsDOIOpen Access PDF

Abstract

Weyl points-topological monopoles of quantized Berry flux-are predicted to spread to Weyl exceptional rings in the presence of non-Hermiticity. Here, we use a one-dimensional Aubry-Andre-Harper model to construct a Weyl semimetal in a three-dimensional parameter space comprising one reciprocal dimension and two synthetic dimensions. The inclusion of non-Hermiticity in the form of gain and loss produces a synthetic Weyl exceptional ring (SWER). The topology of the SWER is characterized by both its topological charge and non-Hermitian winding numbers. We experimentally observe the SWER and synthetic Fermi arc in a one-dimensional phononic crystal with the non-Hermiticity introduced by active acoustic components. Our findings pave the way for studying the high-dimensional non-Hermitian topological physics in acoustics.

Topics & Concepts

PhysicsHermitian matrixWeyl semimetalTopology (electrical circuits)Realization (probability)Theoretical physicsQuantum mechanicsBand gapMathematicsSemimetalCombinatoricsStatisticsTopological Materials and PhenomenaQuantum Mechanics and Non-Hermitian PhysicsNonlinear Photonic Systems
Experimental Realization of Weyl Exceptional Rings in a Synthetic Three-Dimensional Non-Hermitian Phononic Crystal | Litcius