The Laminar Two-Phase Flow, Phase Field, () and Turbulent Two-Phase Flow, Phase Field, () interfaces contain a multiphysics coupling feature, Two-Phase Flow, Phase Field, which is added automatically.

The Two-Phase Flow, Phase Field multiphysics coupling feature defines the density and dynamic viscosity of the fluid used in the Laminar Flow and Turbulent Flow interfaces, and it defines the surface tension on the interface in form of a volume force used in the momentum equation. It also enables the Phase Field interface to use the velocity field calculated from the Laminar Flow or Turbulent Flow interface to transport the interface.

The Label is the default multiphysics coupling feature name.

The Name is used primarily as a scope prefix for variables defined by the coupling node. Refer to such variables in expressions using the pattern <name>.<variable_name>. In order to distinguish between variables belonging to different coupling nodes or physics interfaces, the name string must be unique. Only letters, numbers, and underscores (_) are permitted in the Name field. The first character must be a letter.

The default Name (for the first multiphysics coupling feature Two-Phase Flow, Phase Field in the model) is tpf1.

This section controls which individual interfaces are coupled by the current coupling feature. If a physics interface is deleted and then added to the model again, then in order to reestablish the coupling, you need to choose the correct physics interface again from the Fluid flow or Moving interfaces lists.

By default, the Temperature model input is set to Common model input, and the temperature is controlled from Default Model Inputs under Global Definitions or by a locally defined Model Input. If a Heat Transfer interface is included in the component, it controls the temperature Common model input. Alternatively, the temperature field can be selected from another physics interface. All physics interfaces have their own tags (Name). For example, if a Heat Transfer in Fluids interface is included in the component, the Temperature (ht) option is available for T.

You can also select User defined from the Temperature model input in order to manually prescribe T.

This input appears when a material requires the absolute pressure as a model input. The default Absolute pressure pA is p+pref, where p is the dependent pressure variable from the Navier-Stokes or RANS equations, and pref is from the user input defined at the fluid flow physics interface level.

The Absolute pressure field can be edited by clicking Make All Model Inputs Editable () and entering the desired value in the input field.

Use the corresponding section to specify the properties of the two fluids. The fluids are denoted Fluid 1 and Fluid 2, respectively.

To specify the properties of Fluid 1from a material, select the appropriate material in the Fluid 1 list. Also make sure that the Density of fluid 1ρ1 and Dynamic viscosity of fluid 1μ1 are both set to From Material.

The density in a material can depend on temperature and/or pressure and these dependencies are automatically replaced by pref and Tref for incompressible flows (as specified by the Compressibility setting of the fluid flow interface).

To instead apply a variable or expression for the density or dynamic viscosity for Fluid A, select User defined in the Density of fluid 1 ρ1 or the Dynamic viscosity of fluid 1 μ1 drop down list and enter the expression in the corresponding edit field.

Similarly, the properties of Fluid 2 can be specified.

The fluid defined as Fluid 1 affects the wetting characteristics on wetted walls. See the Wetted Wall node for details.

Select the Include surface tension force in momentum equation check box to include the surface tension force in the momentum equation. If the surface tension force is included, select Include surface tension gradient effects in surface tension force to account for the Marangoni effect due to gradients in the surface tension coefficient.

Select a Surface tension coefficient σ (SI unit: N/m):