Two-dimensional silicon and carbon monochalcogenides with the structure of phosphorene
Two-dimensional silicon and carbon monochalcogenides with the structure of phosphorene
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Date
2017-06-29
Authors
Rocca, Dario
Abboud, Ali
Vaitheeswaran, Ganapathy
Lebègue, Sébastien
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Abstract
Phosphorene has recently attracted significant interest for applications in electronics and optoelectronics. Inspired by this material an ab initio study was carried out on new two-dimensional binary materials with a structure analogous to phosphorene. Specifically, carbon and silicon monochalcogenides have been considered. After structural optimization, a series of binary compounds were found to be dynamically stable in a phosphorene-like geometry: CS, CSe, CTe, SiO, SiS, SiSe, and SiTe. The electronic properties of these monolayers were determined using density functional theory. By using accurate hybrid functionals it was found that these materials are semiconductors and span a broad range of bandgap values and types. Similarly to phosphorene, the computed effective masses point to a strong in-plane anisotropy of carrier mobilities. The variety of electronic properties carried by these compounds have the potential to broaden the technological applicability of two-dimensional materials.
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Keywords
Electronic structure,
Phosphorene,
Two-dimensional materials
Citation
Beilstein Journal of Nanotechnology. v.8(1)