Department of Innovative System Engineering, Nippon Institute of Technology, 4-1 Gakuendai, Miyashiro-machi, Saitama 345-8501, Japan.
Nanoscale Res Lett. 2014 May 29;9(1):269. doi: 10.1186/1556-276X-9-269. eCollection 2014.
To realize the nanofabrication of silicon surfaces using atomic force microscopy (AFM), we investigated the etching of mechanically processed oxide masks using potassium hydroxide (KOH) solution. The dependence of the KOH solution etching rate on the load and scanning density of the mechanical pre-processing was evaluated. Particular load ranges were found to increase the etching rate, and the silicon etching rate also increased with removal of the natural oxide layer by diamond tip sliding. In contrast, the local oxide pattern formed (due to mechanochemical reaction of the silicon) by tip sliding at higher load was found to have higher etching resistance than that of unprocessed areas. The profile changes caused by the etching of the mechanically pre-processed areas with the KOH solution were also investigated. First, protuberances were processed by diamond tip sliding at lower and higher stresses than that of the shearing strength. Mechanical processing at low load and scanning density to remove the natural oxide layer was then performed. The KOH solution selectively etched the low load and scanning density processed area first and then etched the unprocessed silicon area. In contrast, the protuberances pre-processed at higher load were hardly etched. The etching resistance of plastic deformed layers was decreased, and their etching rate was increased because of surface damage induced by the pre-processing. These results show that etching depth can be controlled by controlling the etching time through natural oxide layer removal and mechanochemical oxide layer formation. These oxide layer removal and formation processes can be exploited to realize low-damage mask patterns.
为了利用原子力显微镜(AFM)实现硅表面的纳米加工,我们研究了使用氢氧化钾(KOH)溶液对机械加工的氧化掩模进行的蚀刻。评估了机械预处理的负载和扫描密度对 KOH 溶液蚀刻速率的影响。发现特定的负载范围可以提高蚀刻速率,并且硅的蚀刻速率也随着金刚石尖端滑动去除自然氧化层而增加。相比之下,发现在较高负载下由尖端滑动形成的局部氧化物图案(由于硅的机械化学反应)具有比未处理区域更高的蚀刻抗性。还研究了用 KOH 溶液对机械预处理区域进行蚀刻引起的轮廓变化。首先,在低于和高于剪切强度的应力下通过金刚石尖端滑动处理突起。然后在低负载和低扫描密度下进行机械加工以去除自然氧化层。KOH 溶液首先选择性地蚀刻低负载和低扫描密度处理的区域,然后蚀刻未处理的硅区域。相比之下,在较高负载下预处理的突起几乎不被蚀刻。由于预加工引起的表面损伤,塑性变形层的蚀刻抗性降低,其蚀刻速率增加。这些结果表明,可以通过控制自然氧化层去除和机械化学氧化层形成来控制蚀刻时间,从而控制蚀刻深度。可以利用这些氧化层去除和形成过程来实现低损伤掩模图案。
