Assessing the applied normal load during contact mode AFM: An issue with the conventional approach

2016 International Conference for Students on Applied Engineering (ICSAE) Pub Date : 2016-10-01 DOI:10.1109/ICSAE.2016.7810172

Raheem Al-Musawi, E. Brousseau

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Abstract

Usually, the normal load applied to the tip of an Atomic Force Microscope (AFM) probe during its motion across the surface of a scanned sample is determined assuming the absence of any horizontal force. It is shown that this assumption, applied to tip-based nanomachining experiments, leads to wrong estimations of the applied normal force. During this study, the AFM was operated under the so-called “force-controlled” mode based on the optical lever method where a position sensitive photodiode (PSPD) is used to monitor the reflection of a laser beam from the back of the cantilever probe. Normally, the sensitivity of the PSPD is assumed as a known constant, hence, its voltage output in the vertical direction is utilised to determine the cantilever deflection and the normal load. We show that, due to the action of the horizontal force, the PSPD sensitivity is not a constant. Hence, even if the voltage output of the PSPD is kept constant via the feedback loop of the AFM instrument, the grooves produced with tip-based nanomachining are not equal to the depth of indents which are generated when the AFM stage is static. In particular, the difference was up to 55%.

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在接触模式AFM期间评估施加的正常载荷:传统方法的一个问题

通常，原子力显微镜(AFM)探针在扫描样品表面运动过程中施加在探针尖端的法向载荷是在假设没有任何水平力的情况下确定的。结果表明，在基于尖端的纳米加工实验中，这种假设导致了对施加法向力的错误估计。在本研究中，AFM在所谓的“力控”模式下运行，该模式基于光学杠杆方法，其中使用位置敏感光电二极管(PSPD)来监测从悬臂探针背面反射的激光束。通常，PSPD的灵敏度假设为已知常数，因此，其垂直方向的电压输出用于确定悬臂挠度和正常负载。我们表明，由于水平力的作用，PSPD的灵敏度不是一个常数。因此，即使PSPD的输出电压通过AFM仪器的反馈回路保持恒定，尖端纳米加工产生的凹槽也不等于AFM平台静止时产生的凹痕深度。特别是，差异高达55%。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2016 International Conference for Students on Applied Engineering (ICSAE)

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