Sd2 Graphene: Kagome Band in a Hexagonal Lattice

Miao Zhou; Zheng Liu; Wenmei Ming; Zhengfei Wang; Feng Liu

doi:10.1103/PhysRevLett.113.236802

Sd2 Graphene: Kagome Band in a Hexagonal Lattice

Miao Zhou
, Zheng Liu
, Wenmei Ming
, Zhengfei Wang
, Feng Liu^*

^*Corresponding author for this work

University of Utah
Collaborative Innovation Center of Quantum Matter

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

97 Scopus citations

Abstract

Graphene, made of sp2 hybridized carbon, is characterized with a Dirac band, representative of its underlying 2D hexagonal lattice. The fundamental understanding of graphene has recently spurred a surge in the search for 2D topological quantum phases in solid-state materials. Here, we propose a new form of 2D material, consisting of sd2 hybridized transition metal atoms in hexagonal lattice, called sd2 "graphene." The sd2 graphene is characterized by bond-centered electronic hopping, which transforms the apparent atomic hexagonal lattice into the physics of a kagome lattice that may exhibit a wide range of topological quantum phases. Based on first-principles calculations, room-temperature quantum anomalous Hall states with an energy gap of ∼0.1eV are demonstrated for one such lattice made of W, which can be epitaxially grown on a semiconductor surface of 1/3 monolayer Cl-covered Si(111), with high thermodynamic and kinetic stability.

Original language	English
Article number	236802
Journal	Physical Review Letters
Volume	113
Issue number	23
DOIs	https://doi.org/10.1103/PhysRevLett.113.236802
State	Published - 2 Dec 2014
Externally published	Yes

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abstract = "Graphene, made of sp2 hybridized carbon, is characterized with a Dirac band, representative of its underlying 2D hexagonal lattice. The fundamental understanding of graphene has recently spurred a surge in the search for 2D topological quantum phases in solid-state materials. Here, we propose a new form of 2D material, consisting of sd2 hybridized transition metal atoms in hexagonal lattice, called sd2 {"}graphene.{"} The sd2 graphene is characterized by bond-centered electronic hopping, which transforms the apparent atomic hexagonal lattice into the physics of a kagome lattice that may exhibit a wide range of topological quantum phases. Based on first-principles calculations, room-temperature quantum anomalous Hall states with an energy gap of ∼0.1eV are demonstrated for one such lattice made of W, which can be epitaxially grown on a semiconductor surface of 1/3 monolayer Cl-covered Si(111), with high thermodynamic and kinetic stability.",

author = "Miao Zhou and Zheng Liu and Wenmei Ming and Zhengfei Wang and Feng Liu",

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doi = "10.1103/PhysRevLett.113.236802",

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T2 - Kagome Band in a Hexagonal Lattice

AU - Zhou, Miao

AU - Liu, Zheng

AU - Ming, Wenmei

AU - Wang, Zhengfei

AU - Liu, Feng

PY - 2014/12/2

Y1 - 2014/12/2

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AB - Graphene, made of sp2 hybridized carbon, is characterized with a Dirac band, representative of its underlying 2D hexagonal lattice. The fundamental understanding of graphene has recently spurred a surge in the search for 2D topological quantum phases in solid-state materials. Here, we propose a new form of 2D material, consisting of sd2 hybridized transition metal atoms in hexagonal lattice, called sd2 "graphene." The sd2 graphene is characterized by bond-centered electronic hopping, which transforms the apparent atomic hexagonal lattice into the physics of a kagome lattice that may exhibit a wide range of topological quantum phases. Based on first-principles calculations, room-temperature quantum anomalous Hall states with an energy gap of ∼0.1eV are demonstrated for one such lattice made of W, which can be epitaxially grown on a semiconductor surface of 1/3 monolayer Cl-covered Si(111), with high thermodynamic and kinetic stability.

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Sd2 Graphene: Kagome Band in a Hexagonal Lattice

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