A self-consistent microscopic theory is used to calculate the mobility of rigid univalent ions in methanol, ethanol, and propanol at room temperature. The theoretical predictions are in good agreement with the long-known experimental results. In particular, the theory reproduces the nonmonotonic size dependence of the limiting ionic conductance accurately. The relation between the polar solvation dynamics of an ion and its mobility is clarified. The theory also explains how a dynamical version of the classical solvent–berg model can be recovered for small ions in the limit of slow liquids
Motivated by our recent proposition on the possibility of using dielectric continuum models to inter...
We study the microscopic structure and transport properties of ions in mixtures of 1-butyl-3-methyli...
The limiting ionic conductivities for the alkali metal and halide ions in methanol are reported and ...
A self-consistent microscopic theory is used to calculate the mobility of rigid univalent ions in me...
A self-consistent microscopic theory is used to calculate the mobility of rigid univalent ions in me...
What determines the ionic conductivity of an electrolyte solution has remained a problem of great in...
What determines the ionic conductivity of an electrolyte solution has remained a problem of great in...
635-643Remarkable progress has been made in recent years in our understanding of the molecular dynam...
A microscopic theory of equilibrium solvation and solvation dynamics of a classical, polar, solute m...
A theoretical study of the dielectric friction on an ion moving through a dipolar liquid is presente...
A microscopic study of the solvation dynamics of a rigid ion in liquid methanol is presented. The th...
An analysis is provided of the subnanosecond dynamic solvation of ionic liquids in particular and io...
An analysis is provided of the subnanosecond dynamic solvation of ionic liquids in particular and io...
In this article we present a new, general but simple, microscopic expression for time-dependent solv...
An outstanding problem in the theory of ionic conductivity is a derivation of the well-known Hubbard...
Motivated by our recent proposition on the possibility of using dielectric continuum models to inter...
We study the microscopic structure and transport properties of ions in mixtures of 1-butyl-3-methyli...
The limiting ionic conductivities for the alkali metal and halide ions in methanol are reported and ...
A self-consistent microscopic theory is used to calculate the mobility of rigid univalent ions in me...
A self-consistent microscopic theory is used to calculate the mobility of rigid univalent ions in me...
What determines the ionic conductivity of an electrolyte solution has remained a problem of great in...
What determines the ionic conductivity of an electrolyte solution has remained a problem of great in...
635-643Remarkable progress has been made in recent years in our understanding of the molecular dynam...
A microscopic theory of equilibrium solvation and solvation dynamics of a classical, polar, solute m...
A theoretical study of the dielectric friction on an ion moving through a dipolar liquid is presente...
A microscopic study of the solvation dynamics of a rigid ion in liquid methanol is presented. The th...
An analysis is provided of the subnanosecond dynamic solvation of ionic liquids in particular and io...
An analysis is provided of the subnanosecond dynamic solvation of ionic liquids in particular and io...
In this article we present a new, general but simple, microscopic expression for time-dependent solv...
An outstanding problem in the theory of ionic conductivity is a derivation of the well-known Hubbard...
Motivated by our recent proposition on the possibility of using dielectric continuum models to inter...
We study the microscopic structure and transport properties of ions in mixtures of 1-butyl-3-methyli...
The limiting ionic conductivities for the alkali metal and halide ions in methanol are reported and ...
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