Minimizing open-loop piezoactuator nonlinearity artifacts in atomic force microscope measurements.

IF 1.5 4区 工程技术 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC
Chi-Fu Yen, Sanjeevi Sivasankar
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引用次数: 1

Abstract

Atomic force microscopes (AFMs) are widely used to study molecular interactions with piconewton force sensitivity. In an AFM, interaction forces are measured by reflecting a laser beam off a cantilever onto a position sensitive detector and monitoring cantilever deflection. Precise measurements of interaction forces rely on accurately determining the optical lever sensitivity, i.e., the relationship between cantilever deflection and changes in detector voltage. The optical lever sensitivity is measured by pressing the cantilever against a hard substrate using a piezoactuator and recording the resulting change in detector voltage. However, nonlinearities in the motion of commonly used open-loop piezo actuators introduce significant errors in measured optical lever sensitivities. Here, the authors systematically characterize the effect of piezo actuator hysteresis and creep on errors in optical lever sensitivity and identify measurement conditions that minimize these errors.

Abstract Image

Abstract Image

在原子力显微镜测量中最小化开环压电致动器非线性伪影。
原子力显微镜(AFMs)被广泛用于研究具有皮牛顿力灵敏度的分子相互作用。在AFM中,通过将激光束从悬臂梁反射到位置敏感探测器并监测悬臂梁挠度来测量相互作用力。相互作用力的精确测量依赖于精确地确定光学杠杆的灵敏度,即悬臂梁挠度与探测器电压变化之间的关系。光学杠杆的灵敏度是通过使用压电致动器将悬臂压在坚硬的衬底上并记录探测器电压的变化来测量的。然而,在常用的开环压电致动器的运动非线性引入显著误差测量光学杠杆的灵敏度。在这里,作者系统地描述了压电致动器的滞后和蠕变对光学杠杆灵敏度误差的影响,并确定了最小化这些误差的测量条件。
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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来源期刊
CiteScore
2.70
自引率
0.00%
发文量
146
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