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Temporal multilayer structures in discrete physical systems towards arbitrary-dimensional non-Abelian Aharonov-Bohm interferences

Zhaohui Dong, Xiaoxiong Wu, Yiwen Yang, Penghong Yu, Xianfeng Chen, Luqi Yuan

2024Nature Communications17 citationsDOIOpen Access PDF

Abstract

Temporal modulation recently draws great attentions in wave manipulations, with which one can introduce the concept of temporal multilayer structure, a temporal counterpart of spatially multilayer configurations. This kind of multilayer structure holds temporal interfaces in the time domain, which provides additional flexibility in temporal operations. Here we take this opportunity and propose to simulate a non-Abelian gauge field with a temporal multilayer structure in the discrete physical system. Two basic temporal operations, i.e., the folding/unfolding operation and the phase shift operation are used to design such a temporal multilayer structure, which hence can support noncommutative operations to realize the non-Abelian Aharonov-Bohm interference in the time domain. A two-/three-dimensional non-Abelian gauge field can be built, which may be further extended to higher dimensions. Our work therefore provides a unique platform enabling generalization of non-Abelian physics to arbitrary dimensions and offers a method for wave manipulations with temporal band engineering. The authors proposed a method for simulating non-Abelian Aharonov Bohm interferences with a temporal multilayer structure in the discrete physical system. Such a method for studying non-Abelian physics can be generalized to arbitrary dimensions.

Topics & Concepts

Abelian groupGeneralizationFlexibility (engineering)Computer scienceDomain (mathematical analysis)Physical systemGauge (firearms)Field (mathematics)Gauge theoryPhysicsTheoretical computer scienceTopology (electrical circuits)MathematicsMathematical analysisPure mathematicsQuantum mechanicsHistoryStatisticsArchaeologyCombinatoricsTopological Materials and PhenomenaQuantum Mechanics and Non-Hermitian PhysicsNonlinear Photonic Systems