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Axionic band topology in inversion-symmetric Weyl-charge-density waves

Benjamin J. Wieder, Kuan-Sen Lin, Barry Bradlyn

2020Physical Review Research37 citationsDOIOpen Access PDF

Abstract

In recent theoretical and experimental investigations, researchers have linked the low-energy field theory of a Weyl semimetal gapped with a charge-density wave (CDW) to high-energy theories with axion electrodynamics. However, it remains an open question whether a lattice regularization of the dynamical Weyl-CDW is in fact a single-particle axion insulator (AXI). In this Rapid Communication, we use analytic and numerical methods to study both lattice-commensurate and incommensurate minimal (magnetic) Weyl-CDW phases in the mean-field state. We observe that, as previously predicted from field theory, the two inversion (I)-symmetric Weyl-CDWs with = 0, differ by a topological axion angle = . However, we crucially discover that neither of the minimal Weyl-CDW phases at = 0, is individually an AXI; they are instead quantum anomalous Hall (QAH) and "obstructed" QAH insulators that differ by a fractional translation in the modulated cell, analogous to the two phases of the Su-Schrieffer-Heeger model of polyacetylene. Using symmetry indicators of band topology and non-Abelian Berry phase, we demonstrate that our results generalize to multiband systems with only two Weyl fermions, establishing that minimal Weyl-CDWs unavoidably carry nontrivial Chern numbers that prevent the observation of a static magnetoelectric response. We discuss the experimental implications of our findings and provide models and analysis generalizing our results to nonmagnetic Weyl-and Dirac-CDWs.

Topics & Concepts

AxionPhysicsTopological insulatorTopology (electrical circuits)Lattice (music)Theoretical physicsQuantumPoint reflectionQuantum Hall effectField (mathematics)Quantum mechanicsChern classSemimetalCounterexampleEffective field theoryCompactification (mathematics)Inversion (geology)Quantum field theoryMagnetic fieldSymmetry (geometry)Network topologyQuantum opticsTopological Materials and PhenomenaGraphene research and applications2D Materials and Applications
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