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Two-Dimensional Lattice Model for the Surface States of Topological Insulators

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arxiv 1612.08248 v2 pith:LUMMN5BZ submitted 2016-12-25 cond-mat.mes-hall

Two-Dimensional Lattice Model for the Surface States of Topological Insulators

classification cond-mat.mes-hall
keywords latticemodelstatessurfaceeffectinsulatorspropertiestopological
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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The surface states in three-dimensional (3D) topological insulators (TIs) can be described by a two-dimensional (2D) continuous Dirac Hamiltonian. However, there exists the Fermion doubling problem when putting the continuous 2D Dirac equation into a lattice model. In this letter, we introduce a Wilson term with a zero bare mass into the 2D lattice model to overcome the difficulty. By comparing with a 3D Hamiltonian, we show that the modified 2D lattice model can faithfully describe the low-energy electrical and transport properties of surface states of 3D TIs. So this 2D lattice model provides a simple and cheap way to numerically simulate the surface states of 3D TI nanostructures. Based on the 2D lattice model, we also establish the wormhole effect in a TI nanowire by a magnetic field along the wire and show the surface states being robust against disorder. The proposed 2D lattice model can be extensively applied to study the various properties and effects, such as the transport properties, Hall effect, universal conductance fluctuations, localization effect, etc.. So it paves a new way to study the surface states of the 3D topological insulators.

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