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Bulk-Defect Correspondence in Particle-Hole Symmetric Insulators and Semimetals

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arxiv 1310.7594 v1 pith:X2IS25G4 submitted 2013-10-28 cond-mat.mes-hall

Bulk-Defect Correspondence in Particle-Hole Symmetric Insulators and Semimetals

classification cond-mat.mes-hall
keywords statesboundchargeinsulatorsmicroscopicmodesparticle-holerelated
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Lattices with a basis can host crystallographic defects which share the same topological charge (e.g.~the Burgers vector $\vec b$ of a dislocation) but differ in their microscopic structure of the core. We demonstrate that in insulators with particle-hole symmetry and an odd number of orbitals per site, the microscopic details drastically affect the electronic structure: modifications can create or annihilate non-trivial bound states with an associated fractional charge. We show that this observation is related to the behavior of end modes of a dimerized chain and discuss how the end or defect states are predicted from topological invariants in these more complicated cases. Furthermore, using explicit examples on the honeycomb lattice, we explain how bound states in vacancies, dislocations and disclinations are related to each other and to edge modes and how similar features arise in nodal semimetals such as graphene.

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