Electrolytes are central to life and technology but lack complete understanding. Recent
experiments with highly concentrated electrolytes have revealed electrostatic decay lengths …

A new electrical conductivity model is developed for unassociated electrolyte solutions
based on the Debye–Hückel–Onsager theory. In this model, we assume that a single …

Describing analytically the transport properties of electrolytes, such as their conductivity or
the self-diffusion of the ions, has been a central challenge of chemical physics for almost a …

This study presents a novel model to predict the electrical conductivity of multisalt electrolyte
solutions by incorporating corrections to the ideal behavior due to relaxation and …

Seemingly unrelated experiments such as electrolyte transport through nanotubes, nano-
scale electrochemistry, NMR relaxometry and surface force balance measurements, all …

Classical dynamical density functional theory (DDFT) has become one of the central
modeling approaches in nonequilibrium soft matter physics. Recent years have seen the …

We study the temporal response of the electric current in an electrolyte under a sudden
switch on or switch off of an external electric field of arbitrary magnitude. We use Stochastic …

Electrostatic correlations between ions dissolved in water are known to impact their transport
properties in numerous ways, from conductivity to ion selectivity. The effects of these …

In recent years, the theoretical description of electrical noise and fluctuation-induced effects
in electrolytes has gained a renewed interest, enabled by stochastic field theories like …

The response of ionic solutions to time-varying electric fields, quantified by a frequency-
dependent conductivity, is essential in many electrochemical applications. Yet, it constitutes …