College of Civil Engineering & Mechanics, Xiangtan University, Hunan 411105, China.
Nanoscale. 2018 Sep 13;10(35):16750-16758. doi: 10.1039/c8nr04186e.
First-principles simulations demonstrate the anisotropic and high mobility in the new group monolayer IV-V semiconductors. The strain-engineered bandstructure reveals the conduction bands are sensitive to armchair-direction deformation. By applying strains, the electrical transportation in the armchair direction can be further improved or deteriorated. We use this important feature to achieve the tunable electron mobility in monolayer IV-V semiconductors. The controllable introduction of strain into semiconductors offers an important degree of flexibility in electrical transportation. Meanwhile, our works leads to a new approaches for research on mobility control in two-dimensional semiconductors. These will be useful for novel mechanical-electronic devices related to mobility switching.
第一性原理模拟表明,新型 IV-V 族单层半导体具有各向异性和高迁移率。应变工程的能带结构表明,导带对扶手椅方向的变形敏感。通过施加应变,可以进一步改善或恶化扶手椅方向的电输运。我们利用这一重要特性实现了 IV-V 族单层半导体中可调谐的电子迁移率。应变在半导体中的可控引入为电输运提供了重要的灵活性。同时,我们的工作为二维半导体中迁移率控制的研究提供了新的方法。这对于与迁移率开关相关的新型机械电子器件将是有用的。