Phase behaviour and dynamics in primitive models of molecular ionic liquids

TL;DR

This study uses primitive models and computer simulations to investigate the phase behavior and dynamics of molecular ionic liquids, revealing mechanisms of charge transport and molecular motion relevant to room-temperature ionic liquids.

Contribution

It introduces detailed primitive models incorporating size disparity, charge location, and shape anisotropy, and provides high-precision phase diagrams and dynamic insights through simulations.

Findings

Determined vapour-liquid phase diagrams with high accuracy.

Analyzed ion dynamics including diffusion, viscosity, and conductivity.

Identified molecular mechanisms for charge transport involving translation and rotation.

Abstract

The phase behaviour and dynamics of molecular ionic liquids are studied using primitive models and extensive computer simulations. The models account for size disparity between cation and anion, charge location on the cation, and cation-shape anisotropy, which are all prominent features of important materials such as room-temperature ionic liquids. The vapour-liquid phase diagrams are determined using high-precision Monte Carlo simulations, setting the scene for in-depth studies of ion dynamics in the liquid state. Molecular dynamics simulations are used to explore the structure, single-particle translational and rotational autocorrelation functions, cation orientational autocorrelations, self diffusion, viscosity, and frequency-dependent conductivity. The results reveal some of the molecular-scale mechanisms for charge transport, involving molecular translation, rotation, and association.