Abstract
Modelling dissolution of solids, at temperatures below the melting point, is a much discussed topic within non-equilibrium thermodynamics.
Employing the phase-field method, this work treats the solid-liquid interface as a finite continuous transition between the two phases. The phases are represented by an order parameter which is continuous across the solid-liquid interface.
Coupled transport equations are solved, for the order parameter and solute
mol-fraction. The dissolution is driven by the chemical potential gradient.
As a model system, pure silver and lead are utilized for the solid and liquid phases, respectively.
Employing the phase-field method, this work treats the solid-liquid interface as a finite continuous transition between the two phases. The phases are represented by an order parameter which is continuous across the solid-liquid interface.
Coupled transport equations are solved, for the order parameter and solute
mol-fraction. The dissolution is driven by the chemical potential gradient.
As a model system, pure silver and lead are utilized for the solid and liquid phases, respectively.
