Hybrid electrodes effective for both electrowetting- and dielectrowetting-driven digital microfluidics

Droplet Pub Date : 2023-05-11 DOI:10.1002/dro2.58
Hongyao Geng, Sung Kwon Cho
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引用次数: 4

Abstract

Electrowetting on dielectric (EWOD) and dielectrowetting (DEW) are two major principles to drive droplets in digital microfluidics. EWOD is effective to manipulate (create, transport, split, and merge) conductive droplets being currently used for many biological, chemical, and optical applications. DEW can also manipulate droplets but more efficiently with dielectric (nonconductive) fluids. A digital microfluidic platform efficiently operable by both EWOD and DEW would offer higher versatility in handling a wide range of fluids, regardless of their conductivities. In this regard, this article presents a new hybrid electrode design enabling EWOD and DEW to drive various kinds of droplet fluids on a single platform. In addition, a slippery liquid-infused surface (SLIPS) is integrated with the hybrid electrodes. The SLIPS is well known to resist biofouling and repel sticky fluids, which endows the hybrid electrodes with much wider application spectra. As a result, the present SLIPS-integrated hybrid electrodes facilitate actuating various kinds of fluids which would not be driven by conventional EWOD and/or DEW electrodes. This paper presents the successful transportation of not only conductive fluids including water, protein solution, glycerol, and honey but also nonconductive fluids including dodecane, silicone oil, and light and heavy crude oil, all driven by the SLIPS-integrated hybrid electrodes. The performance comparisons among solid, interdigitating, and hybrid electrodes are made by testing both conductive and nonconductive droplets.

Abstract Image

混合电极对电润湿和介电润湿驱动的数字微流体都有效
电介质电润湿(EWOD)和介电润湿(DEW)是数字微流体中驱动液滴的两个主要原理。EWOD可以有效地操纵(创建、传输、分裂和合并)导电液滴,目前用于许多生物、化学和光学应用。DEW也可以操纵液滴,但使用介电(非导电)流体更有效。EWOD和DEW都能有效操作的数字微流体平台将在处理各种流体方面提供更高的通用性,无论其电导率如何。在这方面,本文提出了一种新的混合电极设计,使EWOD和DEW能够在单个平台上驱动各种液滴。此外,光滑的液体注入表面(SLIPS)与混合电极集成在一起。众所周知,SLIPS可以抵抗生物污垢和排斥粘性流体,这使混合电极具有更宽的应用范围。结果,本发明的SLIPS集成混合电极有助于致动各种流体,这些流体将不会由传统的EWOD和/或DEW电极驱动。本文介绍了SLIPS集成混合电极驱动的不仅包括水、蛋白质溶液、甘油和蜂蜜在内的导电流体,还包括十二烷、硅油以及轻质和重质原油在内的非导电流体的成功输送。通过测试导电液滴和非导电液滴,对固体电极、叉指电极和混合电极的性能进行了比较。
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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CiteScore
6.60
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