Three-Dimensional Structure of Electroosmotic Flow over Heterogeneous Surfaces

Erickson, David; Li, Dongqing

doi:10.1021/jp027724c

Cited by 42 publications

(18 citation statements)

References 33 publications

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“…For example, various researchers have performed theoretical studies of electroosmotic flows in 2-D microchannels driven by time-dependent zeta potentials or a time-dependent external electric field, and have demonstrated that chaotic advection can be induced by time-wise periodic alternations of the zeta potential and can improve the mixing performance as a result (Qian and Bau 2002); these are to be described in the section of active mixing scheme. In addition, chaotic advection or transverse flows can also be induced in three-dimensional steady electroosmotic flows with time-independent zeta potentials through the use of specific surface charge patterning configurations (Ajdari 1996(Ajdari , 2001Erickson and Li 2003;Ng et al 2004;Yang and Chang 2004;Biddiss et al 2004;Chang and Yang 2006). Generally, heterogeneous surface charges or non-uniform time-independent zeta potentials are obtained through passive approaches such as coating the microchannel walls with different materials (Liu et al 2000;Stroock et al 2000;Fushinobu and Nakata 2005) or applying suitable surface-chemistry treatments (Hau et al 2003;Krishnamoorthy et al 2006).…”

Section: Heterogeneous Surface Charge Patterning Enhanced Electroosmomentioning

confidence: 99%

Electrokinetic mixing in microfluidic systems

Chang

Yang

2007

Microfluid Nanofluid

267

150

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The applications of electrokinetics in the development of microfluidic devices have been widely attractive in the past decade. Electrokinetic devices generally require no external mechanical moving parts and can be made portable by replacing the power supply by small battery. Therefore, electrokinetic-based microfluidic systems can serve as a viable tool in creating a lab-on-a-chip (LOC) or micro-total analysis system (TAS) for use in biological and chemical assays. Mixing of analytes and reagents is a critical step in realizing lab-on-a-chip. This step is difficult due to the flow in microscale devices which are typically limited to low Reynolds numbers, turbulence does not readily occur. The mixing of two or more fluid streams in a simple microchannel is dominated by the molecular diffusion effect. The diffusive mixing time is given by t m ~ w 2 /D and the mixing length (l m ) along the downstream channel increases linearly with the Péclet number (i.e. l m ~ Pe×w), where w and D are the channel width and molecular diffusivity. However, the rate of diffusive mixing in microscale channels is very slow compared to the convection of the fluid along the channel since the Péclet number of typical microchannel flows is very high due to biomolecules (e.g. DNA and protein) with relatively low molecular diffusivities. To reduce the mixing time and length, various schemes to enhance micro-mixing have been proposed in the past years. This review reports recent developments in the micro-mixing schemes based on DC and AC electrokinetics. The overview given in this article provides a potential user or researcher of electrokinetic-based technology to select the most favorable mixing scheme for applications in the field of micro-total analysis systems. Mixing principle and chaotic mixingAlthough it is difficult to induce turbulence (so-called Eulerian chaos) in microchannels, an effective mixing in low Reynolds number flow regimes can be obtained by the chaotic advection mechanism (or so-called Lagrangian chaos or laminar chaos), which provides an effective increase in the interfacial contact area and concentration gradient due to reduction of the striation thickness (i.e. diffusion length).In this way, mixing time and length can be considerably reduced. If an exponential reduction of striation thickness should occur, the mixing time and mixing length can be reduced down to t m ~ ln(Pe) and l m ~ ln(Pe), respectively, for chaotic flows in the limit of large Pe. An effective mixing always requires repeated stretching and folding of fluid elements, e.g blanking vortex models. Blinking vortex models are similar to the link twist map (LTM) strategy which is based on a dynamic system theory described in the literature [1]. An LTM is often obtained when the dynamic system has a structure such that the motion can be described by the repeated application of two twist maps. Over the past few years, many effective micromixers have been designed according to the LTM strategy. Micro-mixing based on electrokinetics

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Section: Heterogeneous Surface Charge Patterning Enhanced Electroosmomentioning

confidence: 99%

Electrokinetic mixing in microfluidic systems

Chang

Yang

2007

Microfluid Nanofluid

267

150

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“…In such cases, when the flow is being driven both by a pressure gradient and an applied potential difference, the pressure gradient induces a flow of charge in the diffuse layer and generates a finite voltage called the streaming potential. The electric field in the fluid then is no longer one-dimensional [100]. In such cases, numerical solutions are often needed.…”

Section: (C) Electrokinetics In Microfluidics and Nanofluidicsmentioning

confidence: 99%

Theory, fabrication and applications of microfluidic and nanofluidic biosensors

Prakash

Pinti

Bhushan

2012

Phil. Trans. R. Soc. A.

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Biosensors are a broad array of devices that detect the type and amount of a biological species or biomolecule. Several different types of biosensors have been developed that rely on changes to mechanical, chemical or electrical properties of the transduction or sensing element to induce a measurable signal. Often, a biosensor will integrate several functions or unit operations such as sample extraction, manipulation and detection on a single platform. This review begins with an overview of the current state-of-the-art biosensor field. Next, the review delves into a special class of biosensors that rely on microfluidics and nanofluidics by presenting the underlying theory, fabrication and several examples and applications of microfluidic and nanofluidic sensors.

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“…However, both materials have poor thermal conductivities. Thus, the micro-fluidic devices made by PDMS and glass have difficulty in dissipating the heat which is generated internally when a high electric field is applied between the electrodes (Tang et al 2004;Erickson and Li 2003). Due to the reasons cited above, silicon has been chosen as the material to fabricate the EO heat spreader in the present study.…”

Section: Conceptual Designmentioning

confidence: 99%

An experimental study on an electro-osmotic flow-based silicon heat spreader

Eng

Nithiarasu

Guy

2010

Microfluid Nanofluid

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An experimental study has been carried out to estimate the heat transfer improvement offered by a novel electro-osmotic (EO) heat spreader for microprocessor cooling. The proposed design of the elliptical silicon heat spreader can be fabricated at the back surface of the microprocessor as an integral part. Thus, no extra space may be required. The EO heat spreader developed is 0.6 mm 3 in volume and it contains a pair of thin gold film electrodes of approximately 1 lm thickness for applying an external electric field that induces electro-osmotic flow. The inner channel surfaces of the heat spreader are electrically insulated with a thin SiO 2 layer to minimize current leakage into the wafer. The EO heat spreader constructed is able to generate a flow rate of 0.2028 ll/min at 2 V/mm. With this heat spreader, the temperature of a heat source may be reduced by up to 4°C without the aid of any external mechanical devices. The heat spreader has the potential to make the temperature uniform, if the heat source is non-uniform in nature.

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Three-Dimensional Structure of Electroosmotic Flow over Heterogeneous Surfaces

Cited by 42 publications

References 33 publications

Electrokinetic mixing in microfluidic systems

Electrokinetic mixing in microfluidic systems

Theory, fabrication and applications of microfluidic and nanofluidic biosensors

An experimental study on an electro-osmotic flow-based silicon heat spreader

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