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Autori principali: Noh, Yechan, Riccardi, Demian, Smolyanitsky, Alex
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2504.05569
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author Noh, Yechan
Riccardi, Demian
Smolyanitsky, Alex
author_facet Noh, Yechan
Riccardi, Demian
Smolyanitsky, Alex
contents Aqueous cations permeate subnanoscale pores by crossing free energy barriers dominated by competing enthalpic contributions from transiently decreased ion-solvent and increased ion-pore electrostatic interactions. This commonly accepted view is rooted in the studies of monovalent cation transport. Divalent cations, however, have significantly higher desolvation costs, requiring considerably larger pores to enable retention of the first hydration shell and subsequently transport. We show that this scenario gives rise to a strong enthalpy-entropy competition. Specifically, the first hydration shell is shown to undergo rotational ordering inside the pore, resulting in a tight transition state. Our results shed light on the basic mechanisms of transport barrier formation for aqueous divalent cations permeating nanoporous 2D membranes.
format Preprint
id arxiv_https___arxiv_org_abs_2504_05569
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Entropic modulation of divalent cation transport
Noh, Yechan
Riccardi, Demian
Smolyanitsky, Alex
Mesoscale and Nanoscale Physics
Materials Science
Aqueous cations permeate subnanoscale pores by crossing free energy barriers dominated by competing enthalpic contributions from transiently decreased ion-solvent and increased ion-pore electrostatic interactions. This commonly accepted view is rooted in the studies of monovalent cation transport. Divalent cations, however, have significantly higher desolvation costs, requiring considerably larger pores to enable retention of the first hydration shell and subsequently transport. We show that this scenario gives rise to a strong enthalpy-entropy competition. Specifically, the first hydration shell is shown to undergo rotational ordering inside the pore, resulting in a tight transition state. Our results shed light on the basic mechanisms of transport barrier formation for aqueous divalent cations permeating nanoporous 2D membranes.
title Entropic modulation of divalent cation transport
topic Mesoscale and Nanoscale Physics
Materials Science
url https://arxiv.org/abs/2504.05569