Effect of doping and strain modulations on electron transport in monolayer MoS2

Yanfeng Ge; Wenhui Wan; Wanxiang Feng; Di Xiao; Yugui Yao

doi:10.1103/PhysRevB.90.035414

Effect of doping and strain modulations on electron transport in monolayer MoS2

Yanfeng Ge
, Wenhui Wan
, Wanxiang Feng
, Di Xiao
, Yugui Yao

物理学院

Beijing Institute of Technology
Carnegie Mellon University

科研成果: 期刊稿件 › 文章 › 同行评审

73 引用（Scopus）

摘要

The doping and strain effects on the electron transport of monolayer MoS2 are systematically investigated using the first-principles calculations with Boltzmann transport theory. We estimate the mobility has a maximum 275 cm2/(Vs) in the low doping level under the strain-free condition. Applying a small strain (∼3%) can improve the maximum mobility to 1150 cm2/(Vs) and the strain effect is more significant in the high doping level. We demonstrate that the electric resistance mainly due to the electron transitions between K and Q valleys scattered by the M momentum phonons. However, the strain can effectively suppress this type of electron-phonon coupling by changing the energy difference between the K and Q valleys. This sensitivity of mobility to the external strain may direct the improving electron transport of MoS2.

源语言	英语
文章编号	035414
期刊	Physical Review B - Condensed Matter and Materials Physics
卷	90
期	3
DOI	https://doi.org/10.1103/PhysRevB.90.035414
出版状态	已出版 - 14 7月 2014

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abstract = "The doping and strain effects on the electron transport of monolayer MoS2 are systematically investigated using the first-principles calculations with Boltzmann transport theory. We estimate the mobility has a maximum 275 cm2/(Vs) in the low doping level under the strain-free condition. Applying a small strain (∼3\%) can improve the maximum mobility to 1150 cm2/(Vs) and the strain effect is more significant in the high doping level. We demonstrate that the electric resistance mainly due to the electron transitions between K and Q valleys scattered by the M momentum phonons. However, the strain can effectively suppress this type of electron-phonon coupling by changing the energy difference between the K and Q valleys. This sensitivity of mobility to the external strain may direct the improving electron transport of MoS2.",

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AU - Ge, Yanfeng

AU - Wan, Wenhui

AU - Feng, Wanxiang

AU - Xiao, Di

AU - Yao, Yugui

PY - 2014/7/14

Y1 - 2014/7/14

N2 - The doping and strain effects on the electron transport of monolayer MoS2 are systematically investigated using the first-principles calculations with Boltzmann transport theory. We estimate the mobility has a maximum 275 cm2/(Vs) in the low doping level under the strain-free condition. Applying a small strain (∼3%) can improve the maximum mobility to 1150 cm2/(Vs) and the strain effect is more significant in the high doping level. We demonstrate that the electric resistance mainly due to the electron transitions between K and Q valleys scattered by the M momentum phonons. However, the strain can effectively suppress this type of electron-phonon coupling by changing the energy difference between the K and Q valleys. This sensitivity of mobility to the external strain may direct the improving electron transport of MoS2.

AB - The doping and strain effects on the electron transport of monolayer MoS2 are systematically investigated using the first-principles calculations with Boltzmann transport theory. We estimate the mobility has a maximum 275 cm2/(Vs) in the low doping level under the strain-free condition. Applying a small strain (∼3%) can improve the maximum mobility to 1150 cm2/(Vs) and the strain effect is more significant in the high doping level. We demonstrate that the electric resistance mainly due to the electron transitions between K and Q valleys scattered by the M momentum phonons. However, the strain can effectively suppress this type of electron-phonon coupling by changing the energy difference between the K and Q valleys. This sensitivity of mobility to the external strain may direct the improving electron transport of MoS2.

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Effect of doping and strain modulations on electron transport in monolayer MoS2

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