Slow Rotation of Coaxial Slip Colloidal Spheres about Their Axis

IF 2.5 Q3 CHEMISTRY, PHYSICAL

Colloids and Interfaces Pub Date : 2023-10-12 DOI:10.3390/colloids7040063

Min J. Tsai, Huan J. Keh

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Abstract

The flow field around a straight chain of multiple slip spherical particles rotating steadily in an incompressible Newtonian fluid about their line of centers is analyzed at low Reynolds numbers. The particles may vary in radius, slip coefficient, and angular velocity, and they are permitted to be unevenly spaced. Through the use of a boundary collocation method, the Stokes equation governing the fluid flow is solved semi-analytically. The interaction effects among the particles are found to be noteworthy under appropriate conditions. For the rotation of two spheres, our collocation results for their hydrodynamic torques are in good agreement with the analytical asymptotic solution in the literature obtained by using a method of twin multipole expansions. For the rotation of three spheres, the particle interaction effect indicates that the existence of the third particle can influence the torques exerted on the other two particles noticeably. The interaction effect is stronger on the smaller or less slippery particles than on the larger or more slippery ones. Torque results for the rotation of chains of many particles visibly show the shielding effect among the particles.

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同轴滑移胶体球绕轴缓慢旋转

在低雷诺数条件下，分析了不可压缩牛顿流体中绕中心线稳定旋转的多滑移球形颗粒直链的流场。颗粒可以在半径、滑移系数和角速度上变化，并且它们可以是不均匀间隔的。采用边界配点法，对控制流体流动的Stokes方程进行了半解析求解。在适当的条件下，粒子间的相互作用是值得注意的。对于两个球体的旋转，我们对它们的流体动力力矩的配置结果与文献中用双多极展开法得到的解析渐近解符合得很好。对于三个球体的旋转，粒子相互作用效应表明，第三个粒子的存在会显著影响施加在另外两个粒子上的力矩。相对于较大或较光滑的粒子，较小或较不光滑的粒子的相互作用效果更强。多粒子链旋转的转矩结果明显显示了粒子间的屏蔽效应。

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

Colloids and Interfaces CHEMISTRY, PHYSICAL-

CiteScore

3.90

自引率

4.20%

发文量

审稿时长

10 weeks