Clarke R J, Jensen O E, Billingham J, Pearson A P, Williams P M
School of Mathematical Sciences, University of Nottingham, Nottingham NG7 2RD, United Kingdom.
Phys Rev Lett. 2006 Feb 10;96(5):050801. doi: 10.1103/PhysRevLett.96.050801. Epub 2006 Feb 8.
We consider the thermally driven motion of a microcantilever in a fluid environment near a wall, a configuration characteristic of the atomic force microscope. A theoretical model is presented which accounts for hydrodynamic interactions between the cantilever and wall over a wide range of frequencies and which exploits the fluctuation-dissipation theorem to capture the Brownian dynamics of the coupled fluid-cantilever system. Model predictions are tested against experimental thermal spectra for a cantilever in air and water. The model shows how, in a liquid environment, the effects of non-delta-correlated Brownian forcing appear in the power spectrum, particularly at low frequencies. The model also predicts accurately changes in the spectrum in liquid arising through hydrodynamic wall effects, which we show are strongly mediated by the angle at which the cantilever is tilted relative to the wall.
我们考虑在靠近壁面的流体环境中微悬臂梁的热驱动运动,这是原子力显微镜的一种典型配置。本文提出了一个理论模型,该模型考虑了悬臂梁与壁面在很宽频率范围内的流体动力学相互作用,并利用涨落耗散定理来描述耦合流体 - 悬臂梁系统的布朗动力学。针对空气中和水中悬臂梁的实验热谱对模型预测进行了检验。该模型展示了在液体环境中,非δ相关布朗力的影响如何出现在功率谱中,特别是在低频时。该模型还准确预测了由于流体动力学壁面效应导致的液体中频谱变化,我们表明这种变化强烈地由悬臂梁相对于壁面倾斜的角度所介导。
