Fluid Flow and Mixing Induced by AC Continuous Electrowetting of Liquid Metal Droplet

Self Cite

We present herein a novel method of bipolar field-effect control on DC electroosmosis (DCEO) from a physical point of view, in the context of an intelligent and robust operation tool for stratified laminar streams in microscale systems. In this unique design of the DC flow field-effect-transistor (DC-FFET), a pair of face-to-face external gate terminals are imposed with opposite gate-voltage polarities. Diffuse-charge dynamics induces heteropolar Debye screening charge within the diffuse double layer adjacent to the face-to-face oppositely-polarized gates, respectively. A background electric field is applied across the source-drain terminal and forces the face-to-face counterionic charge of reversed polarities into induced-charge electroosmotic (ICEO) vortex flow in the lateral direction. The chaotic turbulence of the transverse ICEO whirlpool interacts actively with the conventional plug flow of DCEO, giving rise to twisted streamlines for simultaneous DCEO pumping and ICEO mixing of fluid samples along the channel length direction. A mathematical model in thin-layer approximation and the low-voltage limit is subsequently established to test the feasibility of the bipolar DC-FFET configuration in electrokinetic manipulation of fluids at the micrometer dimension. According to our simulation analysis, an integrated device design with two sets of side-by-side, but upside-down gate electrode pair exhibits outstanding performance in electroconvective pumping and mixing even without any externally-applied pressure difference. Moreover, a paradigm of a microdevice for fully electrokinetics-driven analyte treatment is established with an array of reversed bipolar gate-terminal pairs arranged on top of the dielectric membrane along the channel length direction, from which we can obtain almost a perfect liquid mixture by using a smaller magnitude of gate voltages for causing less detrimental effects at a small Dukhin number. Sustained by theoretical analysis, our physical demonstration on bipolar field-effect flow control for the microfluidic device of dual functionalities in simultaneous electroconvective pumping and mixing holds great potential in the development of fully-automated liquid-phase actuators in modern microfluidic systems.

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Section: Methodsmentioning

confidence: 99%

On the Bipolar DC Flow Field-Effect-Transistor for Multifunctional Sample Handing in Microfluidics: A Theoretical Analysis under the Debye–Huckel Limit

Liu

Ren

et al. 2018

Self Cite

“…Yazdanshenas et al [ 24 ] developed a microfluidic Kelvin water dropper that can generate high-voltage electricity through water dripping and also used their device to replace the high-voltage power supply in electrowetting. Hu et al [ 25 ] demonstrated a microfluidic mixer design that utilizes amplified Marangoni chaotic advection induced by alternating current electrowetting of a metal droplet. Ahmed and Kim [ 26 ] presented a numerical parametric study of electroosmotic micro-mixers with heterogeneously charged surface patches on channel walls.…”

Section: Other Electric-field-mediated Phenomena (Seven Papers)mentioning

confidence: 99%

Editorial for the Special Issue on Micro/Nano-Chip Electrokinetics, Volume II

Xuan

Qian

2018

“…One of the most popular applications of LM droplet control is to use its high electrical and thermal conductivity in microfluidics as a micromechanical switch inside microchannels for thermal or electrical conduction [ 18 , 19 , 20 ]. Basic microfluidics components, such as micropumps [ 21 ] and mixers [ 22 ], are achieved by electrowetting (EW) controlled liquid metal droplets as well. Furthermore, Wu et al [ 23 ] have recently developed a wheelchair mobile robot with electrical movement control of LM droplets, thereby largely expanding its application scope.…”

Section: Introductionmentioning

confidence: 99%

A Study of Dielectrophoresis-Based Liquid Metal Droplet Control Microfluidic Device

Tian

Gui

2021

This study presents a dielectrophoresis-based liquid metal (LM) droplet control microfluidic device. Six square liquid metal electrodes are fabricated beneath an LM droplet manipulation pool. By applying different voltages on the different electrodes, a non-uniform electric field is formed around the LM droplet, and charges are induced on the surface of the droplet accordingly, so that the droplet could be driven inside the electric field. With a voltage of ±1000 V applied on the electrodes, the LM droplets are driven with a velocity of 0.5 mm/s for the 2.0 mm diameter ones and 1.0 mm/s for the 1.0 mm diameter ones. The whole chip is made of PDMS, and microchannels are fabricated by laser ablation. In this device, the electrodes are not in direct contact with the working droplets; a thin PDMS film stays between the electrodes and the driven droplets, preventing Joule heat or bubble formation during the experiments. To enhance the flexibility of the chip design, a gallium-based alloy with melting point of 10.6 °C is used as electrode material in this device. This dielectrophoresis (DEP) device was able to successfully drive liquid metal droplets and is expected to be a flexible approach for liquid metal droplet control.