Paper detail

General Phase-Field Model with Stability Requirements on Interfaces in $N$-Dimensional Phase-Field Space

In this paper a general multi-phase-field model is presented which is an extension and modification of the model proposed by Folch and Plapp for three phase fields [R. Folch and M. Plapp, Phys. Rev. E 72 011602 (2005)] to the arbitrary number of phases. In the model a physical constraint requiring that the sum of all phase fields in the system is equal to one is resolved by the method of Lagrange multipliers. Namely, the thermodynamic driving force is reduced to its projection on the plane of the constraint. The general model functions in a $N$-dimensional phase field space were derived which justify the requirements for the stability of the total free energy functional on dual interfaces and hence the absence of "ghost" phases. Furthermore, the case of the different interface energies and mobility parameters on the individual interfaces is resolved in a comprehensive manner. It is shown that the static equilibrium for three or four phases fulfils Young's law for contact angles with high accuracy. Also the model is verified by the quantitative simulation of the solidification in an Al-Cu-Ni alloy in the case of the four-phase transformation reaction. We found the way to control the character of new phase nucleation using additional terms in free energy functional.