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Non-Abelian braiding of Weyl nodes via symmetry-constrained phase transitions

Siyu Chen, Adrien Bouhon, Robert-Jan Slager, Bartomeu Monserrat

2022Physical review. B./Physical review. B37 citationsDOIOpen Access PDF

Abstract

Weyl semimetals are arguably the most paradigmatic form of a gapless topological phase. While the stability of Weyl nodes, as quantified by their topological charge, has been extensively investigated, recent interest has shifted to the manipulation of the location of these Weyl nodes for non-Abelian braiding. To accomplish this braiding it is necessary to drive significant Weyl node motion using realistic experimental parameter changes. We show that a family of phase transitions characterized by certain symmetry constraints impose that the Weyl nodes have to reorganize by a large amount, shifting from one high-symmetry plane to another. Additionally, for a subset of pairs of nodes with nontrivial Euler class topology, this reorganization can only occur through a braiding process with adjacent nodes. As a result, the Weyl nodes are forced to move a large distance across the Brillouin zone and to braid, all driven by small temperature changes, a process we illustrate with ${\mathrm{Cd}}_{2}{\mathrm{Re}}_{2}{\mathrm{O}}_{7}$.

Topics & Concepts

Weyl semimetalBraidTopology (electrical circuits)Symmetry (geometry)PhysicsNode (physics)Brillouin zonePhase transitionAbelian groupWeyl transformationMathematicsTheoretical physicsPure mathematicsGeometryQuantum mechanicsCombinatoricsConformal mapConformal symmetryMaterials scienceComposite materialSemimetalBand gapTopological Materials and PhenomenaGraphene research and applications2D Materials and Applications
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