Subhedar Kiran M, Sharma Indu, Dhakate Sanjay R
Physics and Engineering of Carbon, Division of Materials Physics and Engineering and Academy of Scientific and Innovative Research (AcSIR)-NPL, CSIR-National Physical Laboratory (NPL), New Delhi-12, India.
Phys Chem Chem Phys. 2015 Sep 14;17(34):22304-10. doi: 10.1039/c5cp03541d. Epub 2015 Aug 6.
The type of layer stacking in bilayer graphene has a significant influence on its electronic properties because of the contrast nature of layer coupling. Herein, different geometries of the reaction site for the growth of bilayer graphene by the chemical vapor deposition (CVD) technique and their effects on the nature of layer stacking are investigated. Micro-Raman mapping and curve fitting analysis confirmed the type of layer stacking for the CVD grown bilayer graphene. The samples grown with sandwiched structure such as quartz/Cu foil/quartz along with a spacer, between the two quartz plates to create a sealed space, resulted in Bernal or AB stacked bilayer graphene while the sample sandwiched without a spacer produced the twisted bilayer graphene. The contrast difference in the layer stacking is a consequence of the difference in the growth mechanism associated with different geometries of the reaction site. The diffusion dominated process under quasi-static control is responsible for the growth of twisted bilayer graphene in sandwiched geometry while surface controlled growth with ample and continual supply of carbon in sandwiched geometry along with a spacer, leads to AB stacked bilayer graphene. Through this new approach, an efficient technique is presented to control the nature of layer stacking.
由于层间耦合的特性,双层石墨烯中层堆叠的类型对其电子性质有显著影响。在此,研究了通过化学气相沉积(CVD)技术生长双层石墨烯的反应位点的不同几何结构及其对层堆叠性质的影响。显微拉曼映射和曲线拟合分析确定了CVD生长的双层石墨烯的层堆叠类型。以夹层结构生长的样品,如石英/铜箔/石英,并在两个石英板之间设置一个间隔物以形成密封空间,得到了伯纳尔或AB堆叠的双层石墨烯,而没有间隔物的夹层样品则产生了扭曲的双层石墨烯。层堆叠的这种差异是与反应位点不同几何结构相关的生长机制差异的结果。在准静态控制下以扩散为主导的过程导致了夹层几何结构中扭曲双层石墨烯的生长,而在夹层几何结构中,有间隔物且碳供应充足且持续的情况下,以表面控制生长则导致AB堆叠的双层石墨烯。通过这种新方法,提出了一种控制层堆叠性质的有效技术。