cantera/src/kinetics/BulkKinetics.cpp

154 lines
4.3 KiB
C++

// This file is part of Cantera. See License.txt in the top-level directory or
// at https://cantera.org/license.txt for license and copyright information.
#include "cantera/kinetics/BulkKinetics.h"
#include "cantera/kinetics/Reaction.h"
namespace Cantera
{
BulkKinetics::BulkKinetics(thermo_t* thermo) :
m_ROP_ok(false),
m_temp(0.0)
{
if (thermo) {
addPhase(*thermo);
}
}
bool BulkKinetics::isReversible(size_t i) {
return std::find(m_revindex.begin(), m_revindex.end(), i) < m_revindex.end();
}
void BulkKinetics::getDeltaGibbs(doublereal* deltaG)
{
// Get the chemical potentials of the species in the ideal gas solution.
thermo().getChemPotentials(m_grt.data());
// Use the stoichiometric manager to find deltaG for each reaction.
getReactionDelta(m_grt.data(), deltaG);
}
void BulkKinetics::getDeltaEnthalpy(doublereal* deltaH)
{
// Get the partial molar enthalpy of all species in the ideal gas.
thermo().getPartialMolarEnthalpies(m_grt.data());
// Use the stoichiometric manager to find deltaH for each reaction.
getReactionDelta(m_grt.data(), deltaH);
}
void BulkKinetics::getDeltaEntropy(doublereal* deltaS)
{
// Get the partial molar entropy of all species in the solid solution.
thermo().getPartialMolarEntropies(m_grt.data());
// Use the stoichiometric manager to find deltaS for each reaction.
getReactionDelta(m_grt.data(), deltaS);
}
void BulkKinetics::getDeltaSSGibbs(doublereal* deltaG)
{
// Get the standard state chemical potentials of the species. This is the
// array of chemical potentials at unit activity. We define these here as
// the chemical potentials of the pure species at the temperature and
// pressure of the solution.
thermo().getStandardChemPotentials(m_grt.data());
// Use the stoichiometric manager to find deltaG for each reaction.
getReactionDelta(m_grt.data(), deltaG);
}
void BulkKinetics::getDeltaSSEnthalpy(doublereal* deltaH)
{
// Get the standard state enthalpies of the species.
thermo().getEnthalpy_RT(m_grt.data());
for (size_t k = 0; k < m_kk; k++) {
m_grt[k] *= thermo().RT();
}
// Use the stoichiometric manager to find deltaH for each reaction.
getReactionDelta(m_grt.data(), deltaH);
}
void BulkKinetics::getDeltaSSEntropy(doublereal* deltaS)
{
// Get the standard state entropy of the species. We define these here as
// the entropies of the pure species at the temperature and pressure of the
// solution.
thermo().getEntropy_R(m_grt.data());
for (size_t k = 0; k < m_kk; k++) {
m_grt[k] *= GasConstant;
}
// Use the stoichiometric manager to find deltaS for each reaction.
getReactionDelta(m_grt.data(), deltaS);
}
void BulkKinetics::getRevRateConstants(doublereal* krev, bool doIrreversible)
{
// go get the forward rate constants. -> note, we don't really care about
// speed or redundancy in these informational routines.
getFwdRateConstants(krev);
if (doIrreversible) {
getEquilibriumConstants(m_ropnet.data());
for (size_t i = 0; i < nReactions(); i++) {
krev[i] /= m_ropnet[i];
}
} else {
// m_rkcn[] is zero for irreversible reactions
for (size_t i = 0; i < nReactions(); i++) {
krev[i] *= m_rkcn[i];
}
}
}
bool BulkKinetics::addReaction(shared_ptr<Reaction> r)
{
bool added = Kinetics::addReaction(r);
if (!added) {
return false;
}
double dn = 0.0;
for (const auto& sp : r->products) {
dn += sp.second;
}
for (const auto& sp : r->reactants) {
dn -= sp.second;
}
m_dn.push_back(dn);
if (r->reversible) {
m_revindex.push_back(nReactions()-1);
} else {
m_irrev.push_back(nReactions()-1);
}
return true;
}
void BulkKinetics::addElementaryReaction(ElementaryReaction& r)
{
m_rates.install(nReactions()-1, r.rate);
}
void BulkKinetics::modifyElementaryReaction(size_t i, ElementaryReaction& rNew)
{
m_rates.replace(i, rNew.rate);
}
void BulkKinetics::resizeSpecies()
{
Kinetics::resizeSpecies();
m_conc.resize(m_kk);
m_grt.resize(m_kk);
}
void BulkKinetics::setMultiplier(size_t i, double f) {
Kinetics::setMultiplier(i, f);
m_ROP_ok = false;
}
void BulkKinetics::invalidateCache()
{
Kinetics::invalidateCache();
m_ROP_ok = false;
m_temp += 0.13579;
}
}