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

Park, Jae Suk; Cho, Inhee; Park, Jihee; Kim, Sung Jae

doi:10.1021/acs.langmuir.4c00392

Langmuir

2024

DOI: 10.1021/acs.langmuir.4c00392

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

Jae Suk Park,

Inhee Cho,

Jihee Park

et al.

Abstract: 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 st… Show more

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References 60 publications

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Applied Electric Field Effects on Diffusivity and Electrical Double‐Layer Thickness

Masuduzzaman,

Bakli,

Barisik

et al. 2024

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This study utilizes molecular dynamics (MD) simulations and continuum frameworks to explore electroosmotic flow (EOF) in nanoconfined aqueous electrolytes, offering a promising alternative to conventional micro‐/nanofluidic systems. Although osmotic behavior in these environments is deeply linked to local fluid properties and interfacial dynamics between the fluid and electrolyte solutions, achieving a complete molecular‐level understanding has remained challenging. The findings establish a linear relationship between electric field strength and fluid velocity, uncovering two distinct transport regimes separated by a critical threshold, with a markedly intensified flow in the second regime. It is demonstrated that rising electric field strengths significantly enhance water diffusion coefficients, supported by a detailed analysis of fluid hydration structures, the potential of mean force (PMF), and local stress tensors. Due to the applied electric field strength, the motion of ions and water accelerates, leading to the redistribution of ions and intensification of electrostatic forces. This expands the thickness of the electric double layer (EDL) and amplifies fluid diffusivity, thereby enhancing nanoscale fluid activity. These insights enhance the molecular‐level understanding of EOF and define the stability of flow regimes, providing valuable guidelines for advancing nanofluidic technologies, such as drug delivery systems and lab‐on‐a‐chip devices.

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Applied Electric Field Effects on Diffusivity and Electrical Double‐Layer Thickness

Masuduzzaman,

Bakli,

Barisik

et al. 2024

Small

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

Cited by 1 publication

References 60 publications

Applied Electric Field Effects on Diffusivity and Electrical Double‐Layer Thickness

Applied Electric Field Effects on Diffusivity and Electrical Double‐Layer Thickness

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