Use the Electrode Surface node to model an electrochemical electrode-electrolyte interface between an electrolyte domain and an electrode boundary where the electrode is not included explicitly as a domain in the model geometry. Set the electric potential of the electrode or specify a current condition that the potential of the electrode shall fulfill, and use subnodes to specify the Electrode Reaction and the Double Layer Capacitance at the interface.

This node can only be applied on outer boundaries to electrolyte domains. For interior boundaries between electrolyte and electrode domains, use the Internal Electrode Surface node. For interior boundaries to electrolyte domains, use the Perforated Electrode Surface node.

Use the Add () and Delete () buttons as needed in the table to control the number of species.

The Density and Molar mass, in conjunction with the reaction rates and stoichiometry, defined in the Electrode Reaction subnodes, determine the normal electrode growth rate. The growth rate can be used in conjunction with the Deforming Electrode Surface and Nondeforming Boundary multiphysics couplings to model geometry deformations.

When the Solve for species concentrations variables check box is checked, dependent variables for the molar surface concentration of the dissolving-depositing species are added. These can be used to model the thickness of an dissolving/depositing layer in a time-dependent simulation where the resulting deformation in the model geometry is small and will have negligible impact on the current distribution. In stationary studies, the molar surface concentration variables will be defined but not solved for by default.

The Density of sites parameter will be used to set up the local surface mass balance equations for the fractional surface coverages.

Use the Add () and Delete () buttons as needed in the table to control the number of species. The name of each adsorbing-desorbing Species may be edited in the first column of the table. Use a Site occupancy number larger than unity for species that occupy more than one site at the electrode surface.

According to the settings of the table, the fractional surface coverage variable names will be defined according to xxx.theta_yyy_zzz where xxx is the interface name, yyy the tag of the electrode surface node, and zzz the species name. The variable xxx.thetafree_yyy represents the fraction of free surface sites. These variable names may be used when defining kinetics parameters in Electrode Reaction subnodes.

Specify either a Surface resistance Rfilm (SI unit: Ω·m2) directly or choose the Thickness and conductivity option to calculate the surface resistivity based on a depositing film thickness.

The perturbation parameter is either Electric potential, Electrode potential, Total current, or Average current density, based on the Boundary condition selected in the next section.

This section specifies the potential in the electrode phase of the electrolyte-electrode interface. The electrode potential is used (via the overpotential) by the Electrode Reaction subnodes.

Use the Electric potential option to set the value of the potential explicitly with respect to ground whereas the Electrode potential will set the potential value with respect to a reference potential. Total current, Average current density, and External short all add an extra global degree of freedom for the potential in the electrode phase, set to comply with the chosen condition.

When using the Total current option in 1D or 2D, the boundary area is based either on the Cross-sectional area (1D), or the Out-of-Plane thickness (2D) properties, set on the physics interface top node.

See also the documentation for the Electrode Potential and External Short nodes for further information about these boundary condition.

The Cyclic voltammetry setting varies the electric potential linearly in time as follows when used in conjunction with a Cyclic Voltammetry study step:

More advanced waveforms can be obtained using the Electric potential option with a parameter setting based on Functions found in the Definitions menu.

This boundary condition is only available for the Electroanalysis charge conservation model in the Tertiary Current Distribution, Nernst-Planck (tcd) interface.

The Counter electrode option will set a potential to ensure an overall charge balance of the cell so that the integral of all electrode reaction currents of all electrode surface node sums up to zero.

To display this section, click the Show More Options button () and select Advanced Physics Options in the Show More Options dialog box.

If Cyclic voltammetry is selected as the Boundary condition, the Smoothing of cyclic voltammetry wave functions check box is selected by default and the Smoothing factor defaults to 1·10-3. When enabled, smoothing is applied on the triangular wave around the vertex potentials. The smoothing zone corresponds to the product of the smoothing factor with half the duration of one period of the triangular wave.

The setting determines which equilibrium potential value will be used for defining the primary current distribution constraint. When the First reaction has been selected, the first electrode reaction subnode must be active in the model.

To display this section, click the Show More Options button () and select Advanced Physics Options in the Show More Options dialog box.

The section is available in the Primary Current Distribution and Secondary Current Distribution interfaces when the Current Distribution Model property has been set to Primary.

This section is only available in the Primary Current Distribution and Secondary Current Distribution interfaces when the Current Distribution Model property has been set to Primary. To display this section, click the Show More Options button () and select Advanced Physics Options in the Show More Options dialog box.