Modeling of Electroosmotic Flow and Capillary Electrophoresis with the Joule Heating Effect:  The Nernst−Planck Equation versus the Boltzmann Distribution

Tang, Gongyue; Yang, Chun; Chai, Cheekiong; Gong, Haiqing

doi:10.1021/la0301994

Cited by 58 publications

(50 citation statements)

References 23 publications

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“…Such nonuniform temperature and velocity fields then make the sample front translate faster but more dispersed. The same authors later validated the applicability of PoissonBoltzmann equation in describing the ionic distribution through comparison to the full Nernst-Planck equation [72].…”

Section: Axial Temperature Gradients Due To Thermal End Effectsmentioning

confidence: 96%

Joule heating in electrokinetic flow

2007

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Electrokinetic flow is an efficient means to manipulate liquids and samples in lab-on-a-chip devices. It has a number of significant advantages over conventional pressure-driven flow. However, there exists inevitable Joule heating in electrokinetic flow, which is known to cause temperature variations in liquids and draw disturbances to electric, flow and concentration fields via temperature-dependent material properties. Therefore, both the throughput and the resolution of analytic studies performed in microfluidic devices are affected. This article reviews the recent progress on the topic of Joule heating and its effect in electrokinetic flow, particularly the theoretical and experimental accomplishments from the aspects of fluid mechanics and heat/mass transfer. The primary focus is placed on the temperature-induced flow variations and the accompanying phenomena at the whole channel or chip level.

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Section: Axial Temperature Gradients Due To Thermal End Effectsmentioning

confidence: 96%

Joule heating in electrokinetic flow

2007

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“…Deviation occurs as the channel size-to-Debye length ratio decreases. In that case Boltzmann distribution may not be suitable for nanochannels [3,11]. The EOF field is governed by continuity and modified Navier-Stokes equations…”

Section: Introductionmentioning

confidence: 99%

“…Numerical solutions are the only way to solve these highly coupled set of equations, Eqs. (2)- (11). Numerical solutions are further complicated by the simultaneous presence of three separate length scales, the channel length in millimeters, the channel cross-sectional dimension in microns and EDL thickness in nanometers.…”

Section: Introductionmentioning

confidence: 99%

Effect of Joule heating on electrokinetic transport

Çetin

2008

Electrophoresis

100

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The Joule heating (JH) is a ubiquitous phenomenon in electrokinetic flow due to the presence of electrical potential gradient and electrical current. JH may become pronounced for applications with high electrical potential gradients or with high ionic concentration buffer solutions. In this review, an in-depth look at the effect of JH on electrokinetic processes is provided. Theoretical modeling of EOF and electrophoresis (EP) with the presence of JH is presented and the important findings from the previous studies are examined. A numerical study of a fused-silica capillary PCR reactor powered by JH is also presented to extend the discussion of favorable usage of JH.

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“…The specified flow rate and constant wall temperature were assumed in their study. Tang et al [23][24][25] proposed a numerical model for predicting the Joule heating effect on the temperature, velocity, and concentration distributions in microchannels and microtubes. In their model, the coupled Poisson-Boltzmann, Navier-Stokes, and energy equations were solved.…”

Section: Introductionmentioning

confidence: 99%

Estimation of Joule heating effect on temperature and pressure distribution in electrokinetic‐driven microchannel flows

2006

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In this study we present simple analytical models that predict the temperature and pressure variations in electrokinetic-driven microchannel flow under the Joule heating effect. For temperature prediction, a simple model shows that the temperature is related to the Joule heating parameter, autothermal Joule heating parameter, external cooling parameter, Peclet number, and the channel length to channel hydraulic diameter ratio. The simple model overpredicted the thermally developed temperature compared with the full numerical simulation, but in good agreement with the experimental measurements. The factors that affect the external cooling parameters, such as the heat transfer coefficient, channel configuration, and channel material are also examined based on this simple model. Based on the mass conservation, a simple model is developed that predicts the pressure variations, including the temperature effect. An adverse pressure gradient is required to satisfy the mass conservation requirement. The temperature effect on the pressure gradient is via the temperature-dependent fluid viscosity and electroosmotic velocity.

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Modeling of Electroosmotic Flow and Capillary Electrophoresis with the Joule Heating Effect: The Nernst−Planck Equation versus the Boltzmann Distribution

Cited by 58 publications

References 23 publications

Joule heating in electrokinetic flow

Joule heating in electrokinetic flow

Effect of Joule heating on electrokinetic transport

Estimation of Joule heating effect on temperature and pressure distribution in electrokinetic‐driven microchannel flows

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