Fujita D, Kitahara M, Onishi K, Sagisaka K
Advanced Nano Characterization Center, National Institute for Materials Science, 1-2-1 Sengen, Tsukuba, Ibaraki 305-0047, Japan.
Nanotechnology. 2008 Jan 16;19(2):025705. doi: 10.1088/0957-4484/19/02/025705. Epub 2007 Dec 6.
We have developed an ultrahigh vacuum scanning tunneling microscope with an in situ external stress application capability in order to determine the effects of stress and strain on surface atomistic structures. It is necessary to understand these effects because controlling them will be a key technology that will very likely be used in future nanometer-scale fabrication processes. We used our microscope to demonstrate atomic resolution imaging under external tensile stress and strain on the surfaces of wafers of Si(111) and Si(001). We also successfully observed domain redistribution induced by applying uniaxial stress at an elevated temperature on the surface of a wafer of vicinal Si(100). We confirmed that domains for which an applied tensile stress is directed along the dimer bond become less stable and shrink. This suggests that it may be feasible to fabricate single domain surfaces in a process that controls surface stress and strain.
我们开发了一种具有原位施加外部应力能力的超高真空扫描隧道显微镜,以确定应力和应变对表面原子结构的影响。了解这些影响是必要的,因为控制它们将成为一项关键技术,很可能会在未来的纳米级制造工艺中得到应用。我们使用我们的显微镜展示了在外部拉伸应力和应变下,Si(111)和Si(001)晶片表面的原子分辨率成像。我们还成功地观察到在高温下对近邻Si(100)晶片表面施加单轴应力所引起的畴重新分布。我们证实,施加的拉伸应力沿二聚体键方向的畴变得不太稳定并收缩。这表明在控制表面应力和应变的过程中制造单畴表面可能是可行的。
