单层
准粒子
材料科学
电子能带结构
带隙
物理
拉伤
拉伸应变
凝聚态物理
激子
有效质量(弹簧-质量系统)
纳米技术
量子力学
极限抗拉强度
超导电性
内科学
医学
冶金
作者
Hongliang Shi,Hui Pan,Yong‐Wei Zhang,Boris I. Yakobson
出处
期刊:Physical Review B
[American Physical Society]
日期:2013-04-09
卷期号:87 (15)
被引量:837
标识
DOI:10.1103/physrevb.87.155304
摘要
The quasiparticle (QP) band structures of both strainless and strained monolayer MoS${}_{2}$ are investigated using more accurate many-body perturbation $\mathit{GW}$ theory and maximally localized Wannier functions (MLWFs) approach. By solving the Bethe-Salpeter equation (BSE) including excitonic effects on top of the partially self-consistent $\mathit{GW}$${}_{0}$ (sc$\mathit{GW}$${}_{0}$) calculation, the predicted optical gap magnitude is in good agreement with available experimental data. With increasing strain, the exciton binding energy is nearly unchanged, while optical gap is reduced significantly. The sc$\mathit{GW}$${}_{0}$ and BSE calculations are also performed on monolayer WS${}_{2}$, similar characteristics are predicted and WS${}_{2}$ possesses the lightest effective mass at the same strain among monolayers Mo(S,Se) and W(S,Se). Our results also show that the electron effective mass decreases as the tensile strain increases, resulting in an enhanced carrier mobility. The present calculation results suggest a viable route to tune the electronic properties of monolayer transition-metal dichalcogenides (TMDs) using strain engineering for potential applications in high performance electronic devices.
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