A new kind of 2D topological insulators BiCN with a giant gap and its substrate effects

Botao Fu; Yanfeng Ge; Wenyong Su; Wei Guo; Cheng Cheng Liu

doi:10.1038/srep30003

A new kind of 2D topological insulators BiCN with a giant gap and its substrate effects

Botao Fu, Yanfeng Ge, Wenyong Su, Wei Guo, Cheng Cheng Liu^*

^*Corresponding author for this work

School of Physics

Beijing Institute of Technology

Research output: Contribution to journal › Article › peer-review

14 Citations (Scopus)

Abstract

Based on DFT calculation, we predict that BiCN, i.e., bilayer Bi films passivated with -CN group, is a novel 2D Bi-based material with highly thermodynamic stability, and demonstrate that it is also a new kind of 2D TI with a giant SOC gap (∼1 eV) by direct calculation of the topological invariant Z 2 and obvious exhibition of the helical edge states. Monolayer h-BN and MoS 2 are identified as good candidate substrates for supporting the nontrivial topological insulating phase of the 2D TI films, since the two substrates can stabilize and weakly interact with BiCN via van der Waals interaction and thus hardly affect the electronic properties, especially the band topology. The topological properties are robust against the strain and electric field. This may provide a promising platform for realization of novel topological phases.

Original language	English
Article number	30003
Journal	Scientific Reports
Volume	6
DOIs	https://doi.org/10.1038/srep30003
Publication status	Published - 21 Jul 2016

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title = "A new kind of 2D topological insulators BiCN with a giant gap and its substrate effects",

abstract = "Based on DFT calculation, we predict that BiCN, i.e., bilayer Bi films passivated with -CN group, is a novel 2D Bi-based material with highly thermodynamic stability, and demonstrate that it is also a new kind of 2D TI with a giant SOC gap (∼1 eV) by direct calculation of the topological invariant Z 2 and obvious exhibition of the helical edge states. Monolayer h-BN and MoS 2 are identified as good candidate substrates for supporting the nontrivial topological insulating phase of the 2D TI films, since the two substrates can stabilize and weakly interact with BiCN via van der Waals interaction and thus hardly affect the electronic properties, especially the band topology. The topological properties are robust against the strain and electric field. This may provide a promising platform for realization of novel topological phases.",

author = "Botao Fu and Yanfeng Ge and Wenyong Su and Wei Guo and Liu, {Cheng Cheng}",

year = "2016",

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T1 - A new kind of 2D topological insulators BiCN with a giant gap and its substrate effects

AU - Fu, Botao

AU - Ge, Yanfeng

AU - Su, Wenyong

AU - Guo, Wei

AU - Liu, Cheng Cheng

PY - 2016/7/21

Y1 - 2016/7/21

N2 - Based on DFT calculation, we predict that BiCN, i.e., bilayer Bi films passivated with -CN group, is a novel 2D Bi-based material with highly thermodynamic stability, and demonstrate that it is also a new kind of 2D TI with a giant SOC gap (∼1 eV) by direct calculation of the topological invariant Z 2 and obvious exhibition of the helical edge states. Monolayer h-BN and MoS 2 are identified as good candidate substrates for supporting the nontrivial topological insulating phase of the 2D TI films, since the two substrates can stabilize and weakly interact with BiCN via van der Waals interaction and thus hardly affect the electronic properties, especially the band topology. The topological properties are robust against the strain and electric field. This may provide a promising platform for realization of novel topological phases.

AB - Based on DFT calculation, we predict that BiCN, i.e., bilayer Bi films passivated with -CN group, is a novel 2D Bi-based material with highly thermodynamic stability, and demonstrate that it is also a new kind of 2D TI with a giant SOC gap (∼1 eV) by direct calculation of the topological invariant Z 2 and obvious exhibition of the helical edge states. Monolayer h-BN and MoS 2 are identified as good candidate substrates for supporting the nontrivial topological insulating phase of the 2D TI films, since the two substrates can stabilize and weakly interact with BiCN via van der Waals interaction and thus hardly affect the electronic properties, especially the band topology. The topological properties are robust against the strain and electric field. This may provide a promising platform for realization of novel topological phases.

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A new kind of 2D topological insulators BiCN with a giant gap and its substrate effects

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