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Designing a sp3 structure of carbon T-C9: First-principles calculations

Heng Liu, Qingyang Fan, Jiang Li, Wei Zhang, Yanxing Song, Xinhai Yu, Sining Yun

2020Results in Physics28 citationsDOIOpen Access PDF

Abstract

A novel superhard carbon allotrope T-C9 with an all-sp3 bonding network is theoretically predicted in this work. The new phase of the carbon allotrope has tetragonal symmetry with space group P-4m2, and the structural properties, stability, mechanical anisotropy, mechanical and electronic properties of T-C9 are systematically investigated utilizing density functional theory. T-C9 is mechanically and dynamically stable, and T-C9 is favorable in energy which is lower than T carbon by 0.459 eV/atom at zero pressure. The bulk modulus and shear modulus of T-C9 are calculated to be 328 GPa and 243 GPa, respectively, which are slightly larger than those of T-C5, mC12 and tP40 carbon. The brittleness and superhardness of T-C9 are confirmed by the values of B/G (1.35) and the hardness (66.7 GPa), respectively. In addition, the ratio of the maximum and minimum Young's modulus reveals that T-C9 exhibits anisotropy, especially in the (1 1 0) and (1 1 1) directions. Electronic properties indicate that T-C9 can be considered to be semiconductor material with a wide indirect band gap of 4.128 eV.

Topics & Concepts

Bulk modulusTetragonal crystal systemShear modulusDensity functional theoryMaterials scienceBand gapAnisotropyCarbon fibersElectronic structureModulusElectronic band structureBrittlenessDirect and indirect band gapsThermodynamicsCrystallographyCondensed matter physicsCrystal structureComputational chemistryChemistryComposite materialPhysicsQuantum mechanicsOptoelectronicsComposite numberBoron and Carbon Nanomaterials ResearchDiamond and Carbon-based Materials ResearchMetal and Thin Film Mechanics
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