Using the Species Node
The Reaction Engineering Interface and The Chemistry Interface generate Species nodes in the Model Builder based on the chemical equations entered in the Settings window for Reaction.
Figure 2-3: Species nodes are generated automatically as chemical equations are entered in the Reaction nodes.
As with Reaction features you can add, remove, or deactivate Species features by right-clicking a node in the Model Builder. Deactivation of a species automatically deactivates any reactions in which the species is participating.
In the Reaction Rate section it is possible to alter the definition of the reaction rate of the species. This will override the settings in the Reaction feature, where the rate is defined by the stoichiometry of the reaction(s) in which the species participates.
It is also possible to add individual Species nodes with either reactive or nonreactive species.
Choosing the Species Type
For each species entered, it is possible to change its characteristics by selecting its species type — Bulk species, Surface species, or Solvent.
The Type selection has implications in the calculation of thermodynamic and transport properties.
Bulk species and Surface species, defined per reactor volume and area, respectively, set the mixture’s physical properties dependent upon its composition. However, configuring a species as a Solvent sets the physical properties of the reacting fluid mixture equal to those of the solvent species; specifically, its density, heat capacity, viscosity, and thermal conductivity. The interface also implements a solute-solvent approximation for the interaction of species in the fluid and describes the transport properties accordingly. In material balances this means that the diffusion coefficient is independent of any of the solute’s concentrations, because every solute only interacts with solvent molecules, regardless of the concentration. In addition, the convective term in the flux of species is directly given by the velocity field of the solvent multiplied by the solute concentration.
The Type has implications on the Generate Space-Dependent Model procedure since it determines whether interfaces using a solvent-solute approximation of the reacting fluid mixture (as in The Transport of Diluted Species Interface) or a full multicomponent description of the reacting fluid mixture (as in The Transport of Concentrated Species Interface) should be generated.
Furthermore, the Type affects the reaction kinetics. Solvent sets the species’ concentration to a constant value (the initial species concentration). The Reacting Engineering interface does not formulate a mass balance for the solvent species. This setting corresponds to situations where the solvent does not take part in chemical reactions at all, or where it reacts but is present in large excess.
Valid Species Names
Valid species names consist of a case-sensitive combination of letters, numbers, charge indication and phase indication. With the exception of the “+” and “” signs, the caret character “^”, underscore “_”, and the enclosing characters “()[]{}”, special characters are not allowed. In addition, the first character in a species name must be a letter, or enclosing character, to avoid confusion with the stoichiometric coefficients in the reaction formula.
Charge is indicated in one of the following ways:
Fe++, Fe(++), Fe(2+)
Fe^++, Fe^(++), Fe^(2+), Fe^2+
The charge indication, for example (++), is placed last in the species name, but before any phase indication. The charge is automatically read from the species Name field, or Chemical Formula field, and entered in the Charge field in the associated Species feature.
A valid phase indication consists of a valid species name followed by a valid phase. The phase should be placed last. For example, water in gaseous form is written “H2O(g)”, and a divalent cation of iron in water can be written “Fe^2+(aq)”. Valid phases are:
(g), for gas or vapor
(l), for liquid
(s), for solid
(aq), for aqueous solution
(ads), for adsorbed/surface species
(cd), for condensed phase (solid or liquid)
(fl), for fluid (gas or liquid)
(lc), for crystalline liquid
(cr), for crystalline solid
(am), amorphous solid
(vit), vitreous substance (glass)
(mon), for monomeric form
(pol), for polymeric form
(sln), for solution
Using the phases (ads), (s), (l), (aq), or (g) creates adsorbed, solid, liquid, aqueous, or gaseous species with variable names; speciesname_surf, speciesname_solid, speciesname_liquid, speciesname_aq, or speciesname_gas, respectively. The Type field in the Species feature, is filled in automatically depending on which phase that was used. The phases (s), (l), and (g) give rise to Bulk species, while a species with phase indication (ads) results in a Surface species. (aq) gives rise to aqueous species. Note that the Equilibrium Species Vector remains the same despite the presence of any gaseous or liquid species in the system.
Similar to the labeling rule applying to Reaction nodes, the variable name referring to the contents of a field associated with a Species node is given by the interface Name, followed by the field name, and ending with the species name. For example, the contents of the Rate expression field R for the species roh is assigned the variable name re.R_roh (for the Reaction Engineering interface). Access the definition of all the variables used by a specific node by displaying the Equation View node. To display the node, click the Show More Options button () and select Equation View in the Show More Options dialog box.
Theory for the Reaction Engineering and Chemistry Interfaces
Variable Naming Convention and Namespace