The Tertiary Current Distribution, Nernst-Planck (tcdee) interface (
), found under the
Electrochemistry branch (
) when adding a physics interface, describes the current and potential distribution in an electrochemical cell taking into account the individual transport of charged species (ions) and uncharged species in the electrolyte due to diffusion, migration and convection using the Nernst-Planck equations. The physics interface supports different descriptions of the coupled charge and mass transport in the electrolyte (see
Charge Conservation model below). The electrode kinetics for the charge transfer reactions can be described by using arbitrary expressions or by using the predefined Butler-Volmer and Tafel expressions.
The Label is the physics interface node name that will be shown in the model builder tree.
The Name is used primarily as a scope prefix for variables defined by the physics interface. Refer to such physics interface variables in expressions using the pattern
<name>.<variable_name>. In order to distinguish between variables belonging to different 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 physics interface in the model) is
tcdee.
For 2D components, the Thickness field (default value: 1 m) defines a parameter for the thickness of the geometry perpendicular to the two-dimensional cross-section. The value of this parameter is used, among other things, to automatically calculate the total current from the current density vector. The analogy is valid for other fluxes.
For 1D components, enter a Cross sectional area Ac (SI unit: m
2) to define a parameter for the area of the geometry perpendicular to the 1D component. The value of this parameter is used, amongst other things, to automatically calculate the total current from the current density vector. The analogy is valid for other fluxes. The default is 1 m
2.
Use the Electroneutrality or the
Electroneutrality, water based charge conservation option to model cells with significant concentration gradients of the current-carrying species (ions). The electroneutrality condition implicitly assumes that all major current-carrying ions are included in the model. In addition to the electroneutrality condition, the
Electroneutrality, water based option also adds the water auto-ionization equilibrium condition, including proton and hydroxide transport, when defining the electrolyte equations.
A Supporting electrolyte describes a situation where the major part of the charge is transfered by ions whose concentration can be described as constant.
The Poisson option couples the Nernst-Planck equations for mass transport to the Poisson equation for describing the potential distribution in the electrolyte, without any assumption of electroneutrality. This option is typically used when modeling problems where charge separation effects are of interest, typically within nanometers from an electrode surface.
For the Electroneutrality option, the From electroneutrality list sets the species that is calculated from the corresponding condition. Note that the choice of species to be taken from electroneutrality affects the specific boundary conditions that can be set on the eliminated species. For example, flux and concentration settings cannot be set for the eliminated species, and initial values cannot be provided. The choice can also have an impact on the numerics of the problem.
Concentrations basis function orders higher than
Quadratic are not recommended if transport by convection is dominating in the model.
To display these sections, click the Show button (
) and select
Stabilization. There are two consistent stabilization methods available and selected by default—
Streamline diffusion and
Crosswind diffusion. There is one inconsistent stabilization method,
Isotropic diffusion, which is not selected by default. Any settings unique to this physics interface are listed below.