A derivation of a phase field model with fluid properties

## Abstract The phase‐field method provides a mathematical description for free‐boundary problems associated to physical processes with phase transitions. It postulates the existence of a function, called the phase‐field, whose value identifies the phase at a particular point in space and time. The

The development of accurate and efficient computational tools for phase transformation is a prerequisite in order to predict the microstructure evolution during phase transformation in engineering alloys. Even though the antitrapping phase-field model (PFM) has been developed and is increasingly bei

This paper is concerned with a phase-field model with temperature dependent constraint for the order parameter. In the kinetic equation of the order parameter, we take account of diffusion as well as the undercooled/superheated state which is modelled by means of a hysteresis input-output relation;

We have studied a infinite-range planar XY model in the presence of a random field. We have analyzed the dynamics of the system through a Fokker-Planck formalism, focussing our attention in the long time behaviour. This technique allows to compute exactly the phase diagram of the model.

As found by Bordemann and Hoppe and by Jevicki, a certain non-relativistic model of an irrotational and isentropic fluid, related to membranes and to partons, admits a Poincare symmetry. Bazeia and Jackiw associate this dynamical symmetry to a novel type of fielddependent action on space time. The K