S-Site Substitution Effects on the Structural and Electronic Properties by O, Se, and Te in Monolayer MoS2: First-Principles Calculations

Yun Wei; Ting Yu Chen; Zhi Xin Bai; Zheng Tang Liu; Qi Jun Liu

doi:10.3103/S0027134923030219

S-Site Substitution Effects on the Structural and Electronic Properties by O, Se, and Te in Monolayer MoS²: First-Principles Calculations

Yun Wei, Ting Yu Chen, Zhi Xin Bai, Zheng Tang Liu, Qi Jun Liu

School of Materials Sience and Engineering

Southwest Jiaotong University

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

Abstract

Abstract: We use first-principles calculations density-functional theory to investigate the S-site substitution effects on the structural and electronic properties in monolayer MoS² by O, Se, and Te. The calculated structural parameters show that the changed bond lengths are caused by the different electronegativity and atomic radius. The obtained formation energies indicate that the O doping is exothermic, but the others dopings are endothermic. The electronic structures show that there is a direct-indirect band gap transition from pure monolayer MoS² to chalcogen-doping monolayer MoS². Moreover, the partial density of states is also calculated and analyzed.

Original language	English
Pages (from-to)	376-380
Number of pages	5
Journal	Moscow University Physics Bulletin
Volume	78
Issue number	3
DOIs	https://doi.org/10.3103/S0027134923030219
State	Published - Jun 2023

Keywords

chalcogen-doping
density-functional theory
monolayer MoS

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10.3103/S0027134923030219

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title = "S-Site Substitution Effects on the Structural and Electronic Properties by O, Se, and Te in Monolayer MoS2: First-Principles Calculations",

abstract = "Abstract: We use first-principles calculations density-functional theory to investigate the S-site substitution effects on the structural and electronic properties in monolayer MoS2 by O, Se, and Te. The calculated structural parameters show that the changed bond lengths are caused by the different electronegativity and atomic radius. The obtained formation energies indicate that the O doping is exothermic, but the others dopings are endothermic. The electronic structures show that there is a direct-indirect band gap transition from pure monolayer MoS2 to chalcogen-doping monolayer MoS2. Moreover, the partial density of states is also calculated and analyzed.",

keywords = "chalcogen-doping, density-functional theory, monolayer MoS",

author = "Yun Wei and Chen, {Ting Yu} and Bai, {Zhi Xin} and Liu, {Zheng Tang} and Liu, {Qi Jun}",

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year = "2023",

month = jun,

doi = "10.3103/S0027134923030219",

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volume = "78",

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TY - JOUR

T1 - S-Site Substitution Effects on the Structural and Electronic Properties by O, Se, and Te in Monolayer MoS2

T2 - First-Principles Calculations

AU - Wei, Yun

AU - Chen, Ting Yu

AU - Bai, Zhi Xin

AU - Liu, Zheng Tang

AU - Liu, Qi Jun

PY - 2023/6

Y1 - 2023/6

N2 - Abstract: We use first-principles calculations density-functional theory to investigate the S-site substitution effects on the structural and electronic properties in monolayer MoS2 by O, Se, and Te. The calculated structural parameters show that the changed bond lengths are caused by the different electronegativity and atomic radius. The obtained formation energies indicate that the O doping is exothermic, but the others dopings are endothermic. The electronic structures show that there is a direct-indirect band gap transition from pure monolayer MoS2 to chalcogen-doping monolayer MoS2. Moreover, the partial density of states is also calculated and analyzed.

AB - Abstract: We use first-principles calculations density-functional theory to investigate the S-site substitution effects on the structural and electronic properties in monolayer MoS2 by O, Se, and Te. The calculated structural parameters show that the changed bond lengths are caused by the different electronegativity and atomic radius. The obtained formation energies indicate that the O doping is exothermic, but the others dopings are endothermic. The electronic structures show that there is a direct-indirect band gap transition from pure monolayer MoS2 to chalcogen-doping monolayer MoS2. Moreover, the partial density of states is also calculated and analyzed.

KW - chalcogen-doping

KW - density-functional theory

KW - monolayer MoS

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U2 - 10.3103/S0027134923030219

DO - 10.3103/S0027134923030219

M3 - 文章

AN - SCOPUS:85169671591

SN - 0027-1349

VL - 78

SP - 376

EP - 380

JO - Moscow University Physics Bulletin

JF - Moscow University Physics Bulletin

IS - 3

ER -

S-Site Substitution Effects on the Structural and Electronic Properties by O, Se, and Te in Monolayer MoS²: First-Principles Calculations

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Keywords

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