Department of Physics and Astronomy, Purdue University , West Lafayette, Indiana 47907, United States.
Birck Nanotechnology Center, Purdue University , West Lafayette, Indiana 47907, United States.
ACS Nano. 2016 Apr 26;10(4):4712-8. doi: 10.1021/acsnano.6b01149. Epub 2016 Apr 7.
Using electrical characteristics from three-terminal field-effect transistors (FETs), we demonstrate substantial strain induced band gap tunability in transition metal dichalcogenides (TMDs) in line with theoretical predictions and optical experiments. Devices were fabricated on flexible substrates, and a cantilever sample holder was used to apply uniaxial tensile strain to the various multilayer TMD FETs. Analyzing in particular transfer characteristics, we argue that the modified device characteristics under strain are clear evidence of a band gap reduction of 100 meV in WSe2 under 1.35% uniaxial tensile strain at room temperature. Furthermore, the obtained device characteristics imply that the band gap does not shrink uniformly under strain relative to a reference potential defined by the source/drain contacts. Instead, the band gap change is only related to a change of the conduction band edge of WSe2, resulting in a decrease in the Schottky barrier (SB) for electrons without any change for hole injection into the valence band. Simulations of SB device characteristics are employed to explain this point and to quantify our findings. Last, our experimental results are compared with DFT calculations under strain showing excellent agreement between theoretical predictions and the experimental data presented here.
利用三端场效应晶体管(FET)的电学特性,我们展示了过渡金属二卤化物(TMDs)在理论预测和光学实验范围内的显著应变诱导能带隙可调性。器件在柔性衬底上制造,使用悬臂样品架对各种多层 TMD FET 施加单轴拉伸应变。具体分析传输特性,我们认为应变下的器件特性的变化,明确证明了在室温下单轴 1.35%拉伸应变下,WSe2 的能带隙减小了 100meV。此外,获得的器件特性表明,在应变下,能带隙不会相对于源/漏接触定义的参考电势均匀收缩。相反,能带隙的变化仅与 WSe2 的导带边缘的变化有关,导致肖特基势垒(SB)降低,而电子的注入势垒没有变化,进入价带。我们采用 SB 器件特性的模拟来解释这一点,并量化我们的发现。最后,我们将实验结果与应变下的 DFT 计算进行了比较,结果表明理论预测与这里呈现的实验数据之间具有极好的一致性。
