Hydrodynamic dispersion in long microchannels under conditions of electroosmotic circulation: II. Electrolytes

Bernal, Edxon Eduardo Licón; Kovalchuk, V. I.; Zholkovskiy, E. K.; Yaroshchuk, Andriy

doi:10.1007/s10404-016-1718-1

Cited by 4 publications

(1 citation statement)

References 27 publications

(25 reference statements)

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“…However, note that except for the formation of the AIEZ as a mechanism for the enhancement of ion transport, we cannot ignore the possibility of the eletroosmotic (EO) circulation around the dielectric micropillar structure, which is mainly attributed to the Taylor–Aris dispersion, in complex geometries as pillar-filled systems. ,, In particular, if one side of the ion selective surface is a dead end, such as in a battery electrode, there will be a contribution of the auxiliary microstructures to the ion transport enhancement not only from AIEZ, but also from Aris–Taylor dispersion as the EOF is balanced by a pressure-driven backflow. Nevertheless, the possible effect by EO circulation is still vague in our experimental setup due to the lack of direct evidence of the entire circulating flows with the pillar array installation, while the micropillars successfully suppressed the IDZ expansion.…”

Section: Resultsmentioning

confidence: 99%

Differential Impact of Surface Conduction and Electroosmotic Flow on Ion Transport Enhancement by Microscale Auxiliary Structures

Park,

Cho,

Park

et al. 2024

Langmuir

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Our research investigates the impact of auxiliary structures on ion transport in electrochemical systems such as batteries and microscale desalination units, whose importance for sustainable development has increased dramatically in recent decades. The electrochemical systems typically feature ion-selective surfaces, such as electrodes and ion exchange membranes, where ion depletion can cause performance issues including metal dendrite formation and flow instability. Recent research has shown that auxiliary structures in these electrochemical systems can enhance ion transfer near ion-selective surfaces, thereby resolving the instability problem and improving the energy conversion efficiency of the system. Our study leverages recent advancements in nanoscale electrokinetics to model these auxiliary structures as pillar arrays near an ion exchange membrane in a microchannel. We examine how these structures enhance ion transports relative to the characteristic length scale of microchannel depth and pillars' proximity to the ion-selective surface. Results show that the effect of the pillars varies significantly with their placement. Specifically, in deeper microchannels, where electrokinetic convection is stronger, the closer the auxiliary structure is to the ion-selective membrane, the better the ion transfer. However, in the thinner microchannel, the proximity of the auxiliary structure to the ion selective membrane has a less significant correlation with the ion transfer. Therefore, this finding highlights the importance of spatial arrangement of the auxiliary structures in improving the performance of electrochemical devices. Conclusively, this study can help to better understand energy conversion systems such as fuel cells, salinity gradient power generation systems, and electrochemical desalination systems, where auxiliary structures can be used in the vicinity of ion-selective surfaces. Especially, our fundamental electrokinetic study provides an effective means for designing the efficient electrochemical platforms utilizing micro/nanofluidics.

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Section: Resultsmentioning

confidence: 99%

Differential Impact of Surface Conduction and Electroosmotic Flow on Ion Transport Enhancement by Microscale Auxiliary Structures

Park,

Cho,

Park

et al. 2024

Langmuir

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Deionization shocks in crossflow

et al. 2021

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Shock electrodialysis is a recently developed electrochemical water treatment method that shows promise for water deionization and ionic separations. Although simple models and scaling laws have been proposed, a predictive theory has not yet emerged to fit experimental data and enable system design. Here, we extend and analyze existing “leaky membrane” models for the canonical case of a steady shock in crossflow, as in recent experimental prototypes. Two‐dimensional numerical solutions are compared with analytical boundary‐layer approximations and experimental data. The boundary‐layer theory accurately reproduces the simulation results for desalination, and both models predict the data collapse of the desalination factor with dimensionless current, scaled to the incoming convective flux of cations. The numerical simulation also predicts the water recovery increase with current. Nevertheless, neither approach can quantitatively fit the transition from normal to over‐limiting current, which suggests gaps in our understanding of extreme electrokinetic phenomena in porous media.

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Basic principles and problems in decontamination of natural disperse systems. The electrokinetic treatment of soils

Lysenko

Mishchuk

Kovalchuk

2022

Advances in Colloid and Interface Science

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Hydrodynamic dispersion in long microchannels under conditions of electroosmotic circulation: II. Electrolytes

Cited by 4 publications

References 27 publications

Differential Impact of Surface Conduction and Electroosmotic Flow on Ion Transport Enhancement by Microscale Auxiliary Structures

Differential Impact of Surface Conduction and Electroosmotic Flow on Ion Transport Enhancement by Microscale Auxiliary Structures

Deionization shocks in crossflow

Basic principles and problems in decontamination of natural disperse systems. The electrokinetic treatment of soils

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