First-principles calculations of a robust two-dimensional boron honeycomb sandwiching a triangular molybdenum layer

Sheng Yi Xie; Xian Bin Li; Wei Quan Tian; Nian Ke Chen; Xu Lin Zhang; Yeliang Wang; Shengbai Zhang; Hong Bo Sun

doi:10.1103/PhysRevB.90.035447

First-principles calculations of a robust two-dimensional boron honeycomb sandwiching a triangular molybdenum layer

Sheng Yi Xie, Xian Bin Li^*, Wei Quan Tian, Nian Ke Chen, Xu Lin Zhang, Yeliang Wang, Shengbai Zhang, Hong Bo Sun

^*Corresponding author for this work

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

75 Citations (Scopus)

Abstract

A graphenelike two-dimensional boron honeycomb is inherently prohibited due to its empty π valence band. Based on chemical intuition and first-principles calculations, we design a two-dimensional crystal MoB4 with two graphenelike boron honeycombs sandwiching a triangular molybdenum layer. It has the attractive electronic structure of double Dirac cones near Fermi level with high Fermi velocity, which are contributed by the coupling of Mo d orbitals and B pz orbitals. Such a metal stabilized boron honeycomb system could even have both superconductivity and ferromagnetism through appropriate selection of the metal layer, such as manganese. The unique electronic properties of these two-dimensional systems inspire broad interest in nanoelectronics.

Original language	English
Article number	035447
Journal	Physical Review B - Condensed Matter and Materials Physics
Volume	90
Issue number	3
DOIs	https://doi.org/10.1103/PhysRevB.90.035447
Publication status	Published - 28 Jul 2014
Externally published	Yes

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title = "First-principles calculations of a robust two-dimensional boron honeycomb sandwiching a triangular molybdenum layer",

abstract = "A graphenelike two-dimensional boron honeycomb is inherently prohibited due to its empty π valence band. Based on chemical intuition and first-principles calculations, we design a two-dimensional crystal MoB4 with two graphenelike boron honeycombs sandwiching a triangular molybdenum layer. It has the attractive electronic structure of double Dirac cones near Fermi level with high Fermi velocity, which are contributed by the coupling of Mo d orbitals and B pz orbitals. Such a metal stabilized boron honeycomb system could even have both superconductivity and ferromagnetism through appropriate selection of the metal layer, such as manganese. The unique electronic properties of these two-dimensional systems inspire broad interest in nanoelectronics.",

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AU - Xie, Sheng Yi

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AU - Tian, Wei Quan

AU - Chen, Nian Ke

AU - Zhang, Xu Lin

AU - Wang, Yeliang

AU - Zhang, Shengbai

AU - Sun, Hong Bo

PY - 2014/7/28

Y1 - 2014/7/28

N2 - A graphenelike two-dimensional boron honeycomb is inherently prohibited due to its empty π valence band. Based on chemical intuition and first-principles calculations, we design a two-dimensional crystal MoB4 with two graphenelike boron honeycombs sandwiching a triangular molybdenum layer. It has the attractive electronic structure of double Dirac cones near Fermi level with high Fermi velocity, which are contributed by the coupling of Mo d orbitals and B pz orbitals. Such a metal stabilized boron honeycomb system could even have both superconductivity and ferromagnetism through appropriate selection of the metal layer, such as manganese. The unique electronic properties of these two-dimensional systems inspire broad interest in nanoelectronics.

AB - A graphenelike two-dimensional boron honeycomb is inherently prohibited due to its empty π valence band. Based on chemical intuition and first-principles calculations, we design a two-dimensional crystal MoB4 with two graphenelike boron honeycombs sandwiching a triangular molybdenum layer. It has the attractive electronic structure of double Dirac cones near Fermi level with high Fermi velocity, which are contributed by the coupling of Mo d orbitals and B pz orbitals. Such a metal stabilized boron honeycomb system could even have both superconductivity and ferromagnetism through appropriate selection of the metal layer, such as manganese. The unique electronic properties of these two-dimensional systems inspire broad interest in nanoelectronics.

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First-principles calculations of a robust two-dimensional boron honeycomb sandwiching a triangular molybdenum layer

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