cantera/test/kinetics/rates.cpp
Ray Speth 5958578c40 [Kinetics] Check for negative and non-reactant reaction orders
Allow non-reactant orders for electrochemical reactions

Allow negative orders specifically requested, e.g. by setting the
'negative_orders' option in the CTI definition of the reaction.
2014-11-15 00:47:25 +00:00

147 lines
4.7 KiB
C++

#include "gtest/gtest.h"
#include "cantera/kinetics.h"
#include "cantera/thermo/IdealGasPhase.h"
namespace Cantera
{
#ifndef HAS_NO_PYTHON
TEST(FracCoeff, ConvertFracCoeff)
{
IdealGasPhase thermo1("../data/frac.cti", "gas");
std::vector<ThermoPhase*> phases1;
phases1.push_back(&thermo1);
GasKinetics kinetics1;
importKinetics(thermo1.xml(), phases1, &kinetics1);
IdealGasPhase thermo2("../data/frac.xml", "gas");
std::vector<ThermoPhase*> phases2;
phases2.push_back(&thermo2);
GasKinetics kinetics2;
importKinetics(thermo2.xml(), phases2, &kinetics2);
ASSERT_EQ(thermo2.nSpecies(), thermo1.nSpecies());
ASSERT_EQ(kinetics2.nReactions(), kinetics1.nReactions());
for (size_t i = 0; i < kinetics1.nReactions(); i++) {
for (size_t k = 0; k < thermo1.nSpecies(); k++) {
EXPECT_EQ(kinetics1.reactantStoichCoeff(k,i),
kinetics2.reactantStoichCoeff(k,i));
EXPECT_EQ(kinetics1.productStoichCoeff(k,i),
kinetics2.productStoichCoeff(k,i));
}
}
}
#endif
class FracCoeffTest : public testing::Test
{
public:
FracCoeffTest() :
therm("../data/frac.xml", "gas")
{
std::vector<ThermoPhase*> phases;
phases.push_back(&therm);
importKinetics(therm.xml(), phases, &kin);
therm.setState_TPX(2000, 4*OneAtm,
"H2O:0.5, OH:.05, H:0.1, O2:0.15, H2:0.2");
kH2O = therm.speciesIndex("H2O");
kH = therm.speciesIndex("H");
kOH = therm.speciesIndex("OH");
kO2 = therm.speciesIndex("O2");
kH2 = therm.speciesIndex("H2");
}
IdealGasPhase therm;
GasKinetics kin;
size_t kH2O, kH, kOH, kO2, kH2;
};
TEST_F(FracCoeffTest, StoichCoeffs)
{
EXPECT_DOUBLE_EQ(1.0, kin.reactantStoichCoeff(kH2O, 0));
EXPECT_DOUBLE_EQ(1.4, kin.productStoichCoeff(kH, 0));
EXPECT_DOUBLE_EQ(0.6, kin.productStoichCoeff(kOH, 0));
EXPECT_DOUBLE_EQ(0.2, kin.productStoichCoeff(kO2, 0));
EXPECT_DOUBLE_EQ(0.7, kin.reactantStoichCoeff(kH2, 1));
EXPECT_DOUBLE_EQ(0.6, kin.reactantStoichCoeff(kOH, 1));
EXPECT_DOUBLE_EQ(0.2, kin.reactantStoichCoeff(kO2, 1));
EXPECT_DOUBLE_EQ(1.0, kin.productStoichCoeff(kH2O, 1));
}
TEST_F(FracCoeffTest, RateConstants)
{
vector_fp kf(kin.nReactions(), 0.0);
vector_fp kr(kin.nReactions(), 0.0);
kin.getFwdRateConstants(&kf[0]);
kin.getRevRateConstants(&kr[0]);
// sum of reaction orders is 1.0; kf has units of 1/s
EXPECT_DOUBLE_EQ(1e13, kf[0]);
// sum of reaction orders is 3.8.
// kf = 1e13 (mol/cm^3)^-2.8 s^-1 = 1e13*1000^-2.8 (kmol/m^3)^-2.8 s^-1
EXPECT_NEAR(1e13*pow(1e3, -2.8), kf[1], 1e-2);
// Reactions are irreversible
EXPECT_DOUBLE_EQ(0.0, kr[0]);
EXPECT_DOUBLE_EQ(0.0, kr[1]);
}
TEST_F(FracCoeffTest, RatesOfProgress)
{
vector_fp kf(kin.nReactions(), 0.0);
vector_fp conc(therm.nSpecies(), 0.0);
vector_fp ropf(kin.nReactions(), 0.0);
therm.getConcentrations(&conc[0]);
kin.getFwdRateConstants(&kf[0]);
kin.getFwdRatesOfProgress(&ropf[0]);
EXPECT_DOUBLE_EQ(conc[kH2O]*kf[0], ropf[0]);
EXPECT_DOUBLE_EQ(pow(conc[kH2], 0.8)*conc[kO2]*pow(conc[kOH],2)*kf[1],
ropf[1]);
}
TEST_F(FracCoeffTest, CreationDestructionRates)
{
vector_fp ropf(kin.nReactions(), 0.0);
vector_fp cdot(therm.nSpecies(), 0.0);
vector_fp ddot(therm.nSpecies(), 0.0);
kin.getFwdRatesOfProgress(&ropf[0]);
kin.getCreationRates(&cdot[0]);
kin.getDestructionRates(&ddot[0]);
EXPECT_DOUBLE_EQ(ropf[0], ddot[kH2O]);
EXPECT_DOUBLE_EQ(1.4*ropf[0], cdot[kH]);
EXPECT_DOUBLE_EQ(0.6*ropf[0], cdot[kOH]);
EXPECT_DOUBLE_EQ(0.2*ropf[0], cdot[kO2]);
EXPECT_DOUBLE_EQ(0.7*ropf[1]+ropf[2], ddot[kH2]);
EXPECT_DOUBLE_EQ(0.6*ropf[1], ddot[kOH]);
EXPECT_DOUBLE_EQ(0.2*ropf[1]+0.5*ropf[2], ddot[kO2]);
EXPECT_DOUBLE_EQ(ropf[1]+ropf[2], cdot[kH2O]);
EXPECT_DOUBLE_EQ(0.0, cdot[therm.speciesIndex("O")]);
EXPECT_DOUBLE_EQ(0.0, ddot[therm.speciesIndex("O")]);
}
TEST_F(FracCoeffTest, EquilibriumConstants)
{
vector_fp Kc(kin.nReactions(), 0.0);
vector_fp mu0(therm.nSpecies(), 0.0);
kin.getEquilibriumConstants(&Kc[0]);
therm.getGibbs_ref(&mu0[0]); // at pRef
double deltaG0_0 = 1.4 * mu0[kH] + 0.6 * mu0[kOH] + 0.2 * mu0[kO2] - mu0[kH2O];
double deltaG0_1 = mu0[kH2O] - 0.7 * mu0[kH2] - 0.6 * mu0[kOH] - 0.2 * mu0[kO2];
double pRef = therm.refPressure();
double RT = GasConstant * therm.temperature();
// Net stoichiometric coefficients are 1.2 and -0.5
EXPECT_NEAR(exp(-deltaG0_0/RT) * pow(pRef/RT, 1.2), Kc[0], 1e-13 * Kc[0]);
EXPECT_NEAR(exp(-deltaG0_1/RT) * pow(pRef/RT, -0.5), Kc[1], 1e-13 * Kc[1]);
}
}