Controlling Topological States in Topological/Normal Insulator Heterostructures | Zendy

Marcio Costa | Zendy; A. T. Costa | Zendy; Walter A. Freitas | Zendy; T. M. Schmidt | Zendy; Marco Buongiorno Nardelli | Zendy; A. Fazzio | Zendy

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Controlling Topological States in Topological/Normal Insulator Heterostructures

Author(s) -

Marcio Costa,

A. T. Costa,

Walter A. Freitas,

T. M. Schmidt,

Marco Buongiorno Nardelli,

A. Fazzio

Publication year - 2018

Publication title -

acs omega

Language(s) - Uncategorized

Resource type - Journals

ISSN - 2470-1343

DOI - 10.1021/acsomega.8b01836

Subject(s) - topological insulator , heterojunction , hamiltonian (control theory) , ab initio , band gap , topology (electrical circuits) , insulator (electricity) , density functional theory , spin–orbit interaction , condensed matter physics , materials science , surface states , physics , quantum mechanics , mathematics , optoelectronics , surface (topology) , geometry , combinatorics , mathematical optimization

We have performed a systematic investigation of the nature of the nontrivial interface states in topological/normal insulator (TI/NI) heterostructures. On the basis of first principles and a recently developed scheme to construct ab initio effective Hamiltonian matrices from density functional theory calculations, we studied systems of realistic sizes with high accuracy and control over the relevant parameters such as TI and NI band alignment, NI gap, and spin-orbit coupling strength. Our results for IV-VI compounds show the interface gap tunability by appropriately controlling the NI thickness, which can be explored for device design. Also, we verified the preservation of an in-plane spin texture in the interface-gaped topological states.

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