T-carbon: A novel carbon allotrope

Xian Lei Sheng; Qing Bo Yan; Fei Ye; Qing Rong Zheng; Gang Su

doi:10.1103/PhysRevLett.106.155703

T-carbon: A novel carbon allotrope

Xian Lei Sheng
, Qing Bo Yan
, Fei Ye
, Qing Rong Zheng
, Gang Su^*

^*Corresponding author for this work

University of Chinese Academy of Sciences

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

497 Scopus citations

Abstract

A structurally stable crystalline carbon allotrope is predicted by means of the first-principles calculations. This allotrope can be derived by substituting each atom in diamond with a carbon tetrahedron, and possesses the same space group Fd3̄m as diamond, which is thus coined as T-carbon. The calculations on geometrical, vibrational, and electronic properties reveal that T-carbon, with a considerable structural stability and a much lower density 1.50g/cm3, is a semiconductor with a direct band gap about 3.0 eV, and has a Vickers hardness 61.1 GPa lower than diamond but comparable with cubic boron nitride. Such a form of carbon, once obtained, would have wide applications in photocatalysis, adsoption, hydrogen storage, and aerospace materials.

Original language	English
Article number	155703
Journal	Physical Review Letters
Volume	106
Issue number	15
DOIs	https://doi.org/10.1103/PhysRevLett.106.155703
State	Published - 15 Apr 2011
Externally published	Yes

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title = "T-carbon: A novel carbon allotrope",

abstract = "A structurally stable crystalline carbon allotrope is predicted by means of the first-principles calculations. This allotrope can be derived by substituting each atom in diamond with a carbon tetrahedron, and possesses the same space group Fd{\=3}m as diamond, which is thus coined as T-carbon. The calculations on geometrical, vibrational, and electronic properties reveal that T-carbon, with a considerable structural stability and a much lower density 1.50g/cm3, is a semiconductor with a direct band gap about 3.0 eV, and has a Vickers hardness 61.1 GPa lower than diamond but comparable with cubic boron nitride. Such a form of carbon, once obtained, would have wide applications in photocatalysis, adsoption, hydrogen storage, and aerospace materials.",

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AU - Sheng, Xian Lei

AU - Yan, Qing Bo

AU - Ye, Fei

AU - Zheng, Qing Rong

AU - Su, Gang

PY - 2011/4/15

Y1 - 2011/4/15

N2 - A structurally stable crystalline carbon allotrope is predicted by means of the first-principles calculations. This allotrope can be derived by substituting each atom in diamond with a carbon tetrahedron, and possesses the same space group Fd3̄m as diamond, which is thus coined as T-carbon. The calculations on geometrical, vibrational, and electronic properties reveal that T-carbon, with a considerable structural stability and a much lower density 1.50g/cm3, is a semiconductor with a direct band gap about 3.0 eV, and has a Vickers hardness 61.1 GPa lower than diamond but comparable with cubic boron nitride. Such a form of carbon, once obtained, would have wide applications in photocatalysis, adsoption, hydrogen storage, and aerospace materials.

AB - A structurally stable crystalline carbon allotrope is predicted by means of the first-principles calculations. This allotrope can be derived by substituting each atom in diamond with a carbon tetrahedron, and possesses the same space group Fd3̄m as diamond, which is thus coined as T-carbon. The calculations on geometrical, vibrational, and electronic properties reveal that T-carbon, with a considerable structural stability and a much lower density 1.50g/cm3, is a semiconductor with a direct band gap about 3.0 eV, and has a Vickers hardness 61.1 GPa lower than diamond but comparable with cubic boron nitride. Such a form of carbon, once obtained, would have wide applications in photocatalysis, adsoption, hydrogen storage, and aerospace materials.

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T-carbon: A novel carbon allotrope

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