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Main Authors: Mahata, Thakurdas, Chatterjee, Anirban, Nayak, Ameeya Kumar
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2605.00653
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author Mahata, Thakurdas
Chatterjee, Anirban
Nayak, Ameeya Kumar
author_facet Mahata, Thakurdas
Chatterjee, Anirban
Nayak, Ameeya Kumar
contents The transport and dispersion of multiple species of charged ions are central to many biological and physical processes, including electrokinetic ion separation. However, most theoretical studies of dispersion in channels have focused on neutral solutes, leaving the transport of multiple charged species comparatively unexplored. Differences in ionic diffusivities in a multispecies electrolyte solution generate an self-induced electric fields that drive electromigration. To capture these effects at the macroscopic scale, we combine the lubrication approximation with homogenization theory, under electroneutrality and zero-current constraints, to derive an effective transport equation governing the cross-sectionally averaged concentrations. We apply our model framework to a range of channel geometries and compute the resulting effective dispersion coefficients. Finally, we investigate how channel geometry can be tuned to enhance ionic separation. We observe a geometry-induced electro-diffusive coupling that inhibits solute dispersion in certain channels, leading to a non-monotonic Number of Theoretical Plates (NTP) and making such channels ideal for separation processes.
format Preprint
id arxiv_https___arxiv_org_abs_2605_00653
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Dispersion of multiple charged species in an axially symmetric slowly varying channel
Mahata, Thakurdas
Chatterjee, Anirban
Nayak, Ameeya Kumar
Soft Condensed Matter
The transport and dispersion of multiple species of charged ions are central to many biological and physical processes, including electrokinetic ion separation. However, most theoretical studies of dispersion in channels have focused on neutral solutes, leaving the transport of multiple charged species comparatively unexplored. Differences in ionic diffusivities in a multispecies electrolyte solution generate an self-induced electric fields that drive electromigration. To capture these effects at the macroscopic scale, we combine the lubrication approximation with homogenization theory, under electroneutrality and zero-current constraints, to derive an effective transport equation governing the cross-sectionally averaged concentrations. We apply our model framework to a range of channel geometries and compute the resulting effective dispersion coefficients. Finally, we investigate how channel geometry can be tuned to enhance ionic separation. We observe a geometry-induced electro-diffusive coupling that inhibits solute dispersion in certain channels, leading to a non-monotonic Number of Theoretical Plates (NTP) and making such channels ideal for separation processes.
title Dispersion of multiple charged species in an axially symmetric slowly varying channel
topic Soft Condensed Matter
url https://arxiv.org/abs/2605.00653