Osmotic transport at the aqueous graphene and hBN interfaces: scaling laws from a unified, first principles description

TL;DR

This study uses ab initio simulations to understand osmotic transport at graphene and hBN interfaces, revealing how electronic structure influences ion adsorption and flow, with implications for desalination and energy harvesting.

Contribution

It introduces a first-principles framework to predict osmotic transport properties at 2D material interfaces, highlighting concentration-dependent scaling laws and interface-specific behaviors.

Findings

Differences in osmotic flow and current reversal between graphene and hBN.

Concentration-dependent scaling laws for osmotic responses.

A simple model based on ion and water adsorption length scales.

Abstract

Osmotic transport in nanoconfined aqueous electrolytes provides new venues for water desalination and "blue energy" harvesting; the osmotic response of nanofluidic systems is controlled by the interfacial structure of water and electrolyte solutions in the so-called electrical double layer (EDL), but a molecular-level picture of the EDL is to a large extent still lacking. Particularly, the role of the electronic structure has not been considered in the description of electrolyte/surface interactions. Here, we report enhanced sampling simulations based on ab initio molecular dynamics, aiming at unravelling the free energy of prototypical ions adsorbed at the aqueous graphene and hBN interfaces, and its consequences on nanofluidic osmotic transport. Specifically, we predicted the zeta potential, the diffusio-osmotic mobility and the diffusio-osmotic conductivity for a wide range of salt concentrations from the ab initio water and ion spatial distributions through an analytical framework based on Stokes equation and a modified Poisson-Boltzmann equation. We observed concentration-dependent scaling laws, together with dramatic differences in osmotic transport between the two interfaces, including diffusio-osmotic flow and current reversal on hBN, but not on graphene. We could rationalize the results for the three osmotic responses with a simple model based on characteristic length scales for ion and water adsorption at the surface, which are quite different on graphene and on hBN. Our work provides first principles insights into the structure and osmotic transport of aqueous electrolytes on two-dimensional materials and explores new pathways for efficient water desalination and osmotic energy conversion.