Hydrodynamics of micro-objects near curved surfaces (Presentation Recording)

SPIE NanoScience + Engineering Pub Date : 2015-10-05 DOI:10.1117/12.2190312

Shu Zhang, D. Carberry, T. Nieminen, H. Rubinsztein-Dunlop

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Abstract

Boundary walls have a strong influence on the drag force on optically trapped object near surface. Faxen’s correction has shown how a flat surface modifies the hydrodynamic drag. However, to date, the effect of curved walls at microscopic scale on both translational and rotational movement of micro-objects has not been studied. Here we describe our experiments which aim to study the drag force on optically trapped particles moving near walls with different curvatures. The curved walls were made using 3D laser nano-printing (Nanoscribe), and optical tweezers were used to trap micro-objects near the walls. The translational and rotational motion of the optically trapped particle is related to the drag coefficients. By monitoring the change in the motion of particle, we determined the increase in drag force for particles translating or rotating at different distances from surfaces with different curvatures. These results are essential for calibrating the drag force on particles, and thus enable accurate rheology at the micron-scale. This opens the potential for microrheology under different conditions, such as within microdevices, biological cells and studies of biological processes

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曲面附近微物体的流体力学(演示记录)

边界壁面对近表面光捕获物体的阻力有较大的影响。Faxen的修正显示了平坦的表面是如何改变流体动力阻力的。然而，迄今为止，微观尺度上的弯曲壁对微观物体的平移和旋转运动的影响尚未得到研究。本文描述了我们的实验，目的是研究在不同曲率的壁面附近运动的光捕获粒子的阻力。利用三维激光纳米打印技术(Nanoscribe)制作出弯曲的壁面，并用光学镊子捕获壁面附近的微物体。光捕获粒子的平移和旋转运动与阻力系数有关。通过监测质点运动的变化，我们确定了质点在不同曲率表面上平移或旋转不同距离时阻力的增加。这些结果对于校准颗粒上的阻力至关重要，从而实现微米尺度上的精确流变。这为不同条件下的微流变学开辟了潜力，例如在微设备、生物细胞和生物过程的研究中

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SPIE NanoScience + Engineering

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