Transient solute dispersion in electro‐osmotic viscoplastic flow in a microchannel-Reference-Cited by-同舟云学术

Transient solute dispersion in electro‐osmotic viscoplastic flow in a microchannel

Published:2023-01-30 Issue:6 Volume:103 Page:
ISSN:0044-2267
Container-title:ZAMM - Journal of Applied Mathematics and Mechanics / Zeitschrift für Angewandte Mathematik und Mechanik
language:en
Short-container-title:Z Angew Math Mech

Author:

Roy Ashis Kumar¹,Debnath Sudip²^ORCID,Bég O. Anwar³

Affiliation:

1. Department of Science and Humanities, Narsingarh Tripura Institute of Technology Tripura India

2. Division of Mathematics School of Advanced Sciences Vellore Institute of Technology Chennai India

3. Multi‐Physical Engineering Sciences Group Mechanical Engineering Department School of Science Engineering and Environment (SEE) University of Salford Manchester UK

Abstract

AbstractThe transport of a neutral solute in incompressible electro‐osmotic flow of Bingham plastic non‐Newtonian liquid flowing through a microchannel is studied theoretically. The flow is driven by a constant axially applied electric field. The non‐dimensional conservation equations with associated boundary conditions are solved with Gill's series expansion technique. The whole transport process is analyzed using three transport coefficients, namely, advection coefficient, dispersion coefficient and the apparent asymmetry coefficient, respectively. The mean concentration distribution of the solute is calculated via a third‐order approximation of the series expansion. The study investigates the collective effects of yield stress and electric double layer (EDL) thickness (inverse Debye length) on the transport of solute. The long‐term behaviour of mean concentration distribution is shown to be accurately predicted by second‐order approximations; however, utilizing third or higher order approximations in Gill's series expansion enables a more refined analysis of the small and moderate time behavior of transport coefficients. The present analysis is relevant to emerging applications in bio‐microfluidics exploiting electroviscous fluent media.

Publisher

Wiley

Subject

Applied Mathematics,Computational Mechanics

Link

https://onlinelibrary.wiley.com/doi/pdf/10.1002/zamm.202200260

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