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Theoretical framework for confined ion transport in two-dimensional nanochannels

Shouwei Liao, Yanchang Liu, Libo Li, Li Ding, Yanying Wei, Haihui Wang

2025Nature Communications32 citationsDOIOpen Access PDF

Abstract

Abstract Quantitative understanding of ion transport mechanism is crucial for numerous applications of two-dimensional (2D) nanochannels, but is far from being resolved. Here, we formulated a theoretical framework for both self-diffusion and electromigration of hydrated monatomic ions in various 2D nanochannels (e.g. graphene, h-BN, g-C 3 N 4 , MoS 2 ), by molecular dynamics simulations. The self-diffusivity and mobility of ions in 2D nanochannels both increases linearly with ion-wall distance for small hydrated ions, yet keeps constant for large ones. The underlying mechanism reveals that when ions approach water-layers in nanochannels or possess large hydration shell, their hydration shells become severely distorted. This increases the free energy difference between hydration shell and the surrounding water-layers, water residence time in hydration shell and ion-water friction. Several involving quantitative relations were revealed, with Nernst–Einstein relation validated with both simulations and theoretical derivation. This work shows profound implications for various applications, including ion-sieving, nanodevices and nano-power generators, etc.

Topics & Concepts

IonChemical physicsSolvation shellDiffusionMaterials scienceThermal diffusivityMonatomic ionNanofluidicsMolecular dynamicsGrapheneNanotechnologyIon transporterChemistryThermodynamicsSolvationComputational chemistryPhysicsOrganic chemistryNanopore and Nanochannel Transport StudiesMembrane-based Ion Separation TechniquesFuel Cells and Related Materials
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