Cantera  3.1.0b1
Loading...
Searching...
No Matches

The classes defined here implement simple operations that are used by class Kinetics to compute things like rates of progress, species production rates, etc. More...

Collaboration diagram for Stoichiometry:

Detailed Description

The classes defined here implement simple operations that are used by class Kinetics to compute things like rates of progress, species production rates, etc.

In general, a reaction mechanism may involve many species and many reactions, but any given reaction typically only involves a few species as reactants, and a few as products. Therefore, the matrix of stoichiometric coefficients is very sparse. Not only is it sparse, but the non-zero matrix elements often have the value 1, and in many cases no more than three coefficients are non-zero for the reactants and/or the products.

For the present purposes, we will consider each direction of a reversible reaction to be a separate reaction. We often need to compute quantities that can formally be written as a matrix product of a stoichiometric coefficient matrix and a vector of reaction rates. For example, the species creation rates are given by

\[ \dot C_k = \sum_k \nu^{(p)}_{k,i} R_i \]

where \( \nu^{(p)_{k,i}} \) is the product-side stoichiometric coefficient of species k in reaction i. This could be done by straightforward matrix multiplication, but would be inefficient, since most of the matrix elements of \( \nu^{(p)}_{k,i} \) are zero. We could do better by using sparse-matrix algorithms to compute this product.

If the reactions are general ones, with non-integral stoichiometric coefficients, this is about as good as we can do. But we are particularly concerned here with the performance for very large reaction mechanisms, which are usually composed of elementary reactions, which have integral stoichiometric coefficients. Furthermore, very few elementary reactions involve more than 3 product or reactant molecules.

But we can do even better if we take account of the special structure of this matrix for elementary reactions involving three or fewer product molecules (or reactant molecules).

To take advantage of this structure, reactions are divided into four groups. These classes are designed to take advantage of this sparse structure when computing quantities that can be written as matrix multiplies.

They are designed to explicitly unroll loops over species or reactions for operations on reactions that require knowing the reaction stoichiometry.

This module consists of class StoichManagerN, and classes C1, C2, and C3. Classes C1, C2, and C3 handle operations involving one, two, or three species, respectively, in a reaction. Instances are instantiated with a reaction number, and n species numbers (n = 1 for C1, etc.). All three classes have the same interface.

These classes are designed for use by StoichManagerN, and the operations implemented are those needed to efficiently compute quantities such as rates of progress, species production rates, reaction thermochemistry, etc. The compiler will inline these methods into the body of the corresponding StoichManagerN method, and so there is no performance penalty (unless inlining is turned off).

To describe the methods, consider class C3 and suppose an instance is created with reaction number irxn and species numbers k0, k1, and k2.

The function multiply() is usually used when evaluating the forward and reverse rates of progress of reactions. The rate constants are usually loaded into out[]. Then multiply() is called to add in the dependence of the species concentrations to yield a forward and reverse rop.

The function incrementSpecies() and its cousin decrementSpecies() is used to translate from rates of progress to species production rates. The vector in[] is preloaded with the rates of progress of all reactions. Then incrementSpecies() is called to increment the species production vector, out[], with the rates of progress.

The functions incrementReaction() and decrementReaction() are used to find the standard state equilibrium constant for a reaction. Here, output[] is a vector of length number of reactions, usually the standard Gibbs free energies of reaction, while input, usually the standard state Gibbs free energies of species, is a vector of length number of species.

Note the stoichiometric coefficient for a species in a reaction is handled by always assuming it is equal to one and then treating reactants and products for a reaction separately. Bimolecular reactions involving the identical species are treated as involving separate species.

The methods resizeCoeffs(), derivatives() and scale() are used for the calculation of derivatives with respect to species mole fractions. In this context, resizeCoeffs() is used to establish a mapping between a reaction and corresponding non-zero entries of the sparse derivative matrix of the reaction rate-of-progress vector, which itself is evaluated by the derivatives() method. The scale() method is used to multiply rop entries by reaction order and a user-supplied factor.

Classes

class  C1
 Handles one species in a reaction. More...
 
class  C2
 Handles two species in a single reaction. More...
 
class  C3
 Handles three species in a reaction. More...
 
class  C_AnyN
 Handles any number of species in a reaction, including fractional stoichiometric coefficients, and arbitrary reaction orders. More...
 
class  StoichManagerN
 This class handles operations involving the stoichiometric coefficients on one side of a reaction (reactant or product) for a set of reactions comprising a reaction mechanism. More...