Dielectrophoretic Force Equilibrium of Complex Particles

arXiv: Soft Condensed Matter Pub Date : 2020-07-02 DOI:10.1103/PHYSREVAPPLIED.14.054047

T. Elkeles, P. García-Sánchez, Wu Yue, A. Ramos, G. Yossifon

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引用次数: 1

Abstract

In contrast to the commonly used spherical Janus particles, here we used engineered Janus particles that are fabricated using photolithography technique for precise control over their geometry and coated regions. Specifically, we studied a lollipop-shaped complex particle where its head is coated with gold while its tail is left bare. Due to their distinct electrical properties (i.e. electrical polarizability) the particle exhibits force equilibrium where opposite dielectrophoretic forces acting on its head and tail exactly cancel each other to yield a stable equilibrium position. This was realized in a quadrupolar electrode array where the equilibrium position of the engineered particle could be tuned by the frequency. This stands in contrast to the standard dielectrophoretic behavior where the particle shifts positions from either the center of the quad to the very edge of the electrodes when shifting from a negative to positive dielectrophoretic response, respectively. This opens new opportunities for positioning control of such complex particles for self-assembly, biosensing, biomimetic spermatozoa and more.

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复杂粒子的介电泳力平衡

与通常使用的球形Janus颗粒不同，这里我们使用了利用光刻技术制造的工程Janus颗粒，以精确控制其几何形状和涂覆区域。具体来说，我们研究了一种棒棒糖形状的复杂粒子，它的头部包裹着一层黄金，而尾巴则裸露在外。由于其独特的电学性质(即电极化性)，粒子表现出力平衡，其中作用在其头部和尾部的相反介电泳力完全相互抵消，从而产生稳定的平衡位置。这是在四极电极阵列中实现的，其中工程粒子的平衡位置可以通过频率来调节。这与标准的介电泳行为形成对比，在标准的介电泳行为中，当粒子从负的介电泳响应转变为正的介电泳响应时，粒子的位置分别从四边形的中心转移到电极的边缘。这为自组装、生物传感、仿生精子等复杂粒子的定位控制开辟了新的机会。

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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arXiv: Soft Condensed Matter

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