This work presents a method for force calibration of rectangular atomic force microscopy (AFM) microcantilevers under heavy fluid loading. Theoretical modeling of the thermal response of microcantilevers is discussed including a fluid-structure interaction model of the cantilever-fluid system that incorporates the results of the fluctuation-dissipation theorem. This model is curve fit to the measured thermal response of a cantilever in de-ionized water and a cost function is used to quantify the difference between the theoretical model and measured data. The curve fit is performed in a way that restricts the search space to parameters that reflect heavy fluid loading conditions. The resulting fitting parameters are used to calibrate the cantilever. For comparison, cantilevers are calibrated using Sader's method in air and the thermal noise method in both air and water. For a set of eight cantilevers ranging in stiffness from 0.050 to 5.8 N/m, the maximum difference between Sader's calibration performed in air and the new method performed in water was 9.4%. A set of three cantilevers that violate the aspect ratio assumption associated with the fluid loading model (length-to-width ratios less than 3.5) ranged in stiffness from 0.85 to 4.7 N/m and yielded differences as high as 17.8%. (C) 2009 American Institute of Physics. [doi:10.1063/1.3263907]
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机译:这项工作提出了一种在重载下对矩形原子力显微镜(AFM)微型悬臂进行力校准的方法。讨论了微悬臂梁热响应的理论模型,其中包括悬臂-流体系统的流固耦合模型,该模型包含了波动耗散定理的结果。该模型与去离子水中测得的悬臂的热响应曲线拟合,并且使用成本函数来量化理论模型和测得数据之间的差异。曲线拟合的执行方式是将搜索空间限制为反映重载条件的参数。产生的拟合参数用于校准悬臂。为了进行比较,悬臂是在空气中使用Sader法和在空气和水中都采用热噪声法来校准的。对于一组八个悬臂,其刚度范围从0.050到5.8 N / m,在空气中进行的Sader校准与在水中进行的新方法之间的最大差值为9.4%。一组三个悬臂违反了与流体载荷模型相关的长宽比假设(长宽比小于3.5),刚度从0.85到4.7 N / m不等,差异高达17.8%。 (C)2009美国物理研究所。 [doi:10.1063 / 1.3263907]
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