cantera/test_problems/cathermo/HMW_graph_GvT/Gex_standalone.cpp
2015-08-02 23:06:14 -04:00

139 lines
3.7 KiB
C++

#include <cstdio>
#include <cstdlib>
#include <cmath>
using namespace std;
double Beta0(double temp)
{
double q1 = 0.0765;
double q2 = -777.03;
double q3 = -4.4706;
double q4 = 0.008946;
double q5 = -3.3158E-6;
double tref = 298.15;
return q1 + q2 * (1.0/temp - 1.0/tref)
+ q3 * (log(temp/tref)) + q4 * (temp - tref)
+ q5 * (temp * temp - tref * tref);
}
double Beta1(double temp)
{
double q6 = 0.2664;
double q9 = 6.1608E-5;
double q10 = 1.0715E-6;
double tref = 298.15;
return q6 + q9 * (temp - tref)
+ q10 * (temp * temp - tref * tref);
}
double Cphi(double temp)
{
double q11 = 0.00127;
double q12 = 33.317;
double q13 = 0.09421;
double q14 = -4.655E-5;
double tref = 298.15;
return q11 + q12 * (1.0/temp - 1.0/tref)
+ q13 * (log(temp/tref)) + q14 * (temp - tref);
}
void calc(double temp, double Iionic)
{
double Aphi = 0.0;
if (temp == 323.15) {
Aphi = 0.4102995331359;
} else if (temp == 473.15) {
Aphi = 0.622777;
} else {
printf("ERROR: unknown temp\n");
exit(-1);
}
printf(" Aphi = %g\n", Aphi);
double beta0 = Beta0(temp);
printf(" beta0 = %g\n", beta0);
double beta1 = Beta1(temp);
printf(" beta1 = %g\n", beta1);
double cphi = Cphi(temp);
printf(" Cphi = %g\n", cphi);
double vm = 1.0;
double vx = 1.0;
double v = vm + vx;
double m = Iionic;
double zm = 1.;
double zx = 1.0;
double sqrtI = sqrt(Iionic);
double alpha = 2.0;
double b = 1.2;
double osm1 = - zm * zx * Aphi * sqrtI / (1.0 + b * sqrtI)
+ m * 2.0 * vm * vx / v * (beta0 + beta1 * exp(- alpha * sqrtI))
+ m * m * 2 * pow((vm*vx), 1.5) / v * cphi;
double os = osm1 + 1.0;
double a2 = alpha * alpha;
printf("osmotic coeff = %20.13g\n", os);
double lnmeanAct = - zm * zx * Aphi *
(sqrtI / (1.0 + b * sqrtI) + 2 / b * log(1.0 + b * sqrtI)) +
m * 2 * vm * vx / v * (2.0 * beta0 +
2.0 * beta1/ (a2 * Iionic)
* (1.0- (1.0 + alpha* sqrtI - a2*Iionic/2.0)* exp(- alpha * sqrtI))
)
+ 3.0 * m * m / 2.0 * (2 * sqrt(vm * vx) * vm * vx / v) * cphi;
printf("ln(meanac) = %20.13g\n", lnmeanAct);
double actCoeff = exp(lnmeanAct);
printf("actCoeff = %20.13g\n", actCoeff);
/*
* Gas constant in J gmol-1 K-1
*/
double GasConst = 8.314472;
double gex = v * m * GasConst * 1.0E-3 * temp * (-osm1 + lnmeanAct);
printf(" Gex = %20.13g kJ/kg_water\n", gex);
double RT = GasConst * temp * 1.0E-3;
double IdealMixing = 2.0 * RT * m * (log(m) - 1.0);
printf(" IdealMixing = %20.13g kJ/kg_water\n", IdealMixing);
double DelG = gex + IdealMixing;
printf(" G - G0 = %20.13g kJ/kg_water\n", DelG);
double mu0[6], mu[6];
mu0[0] = -307.76256;
double molecWeight = 18.01528;
double diff = - RT * molecWeight / 1000. * 2. * m * os;
mu[0] = mu0[0] + diff;
printf("mus_kJ/gmol - H2O(L) - %20.13g %20.13g\n", mu0[0], mu[0]);
printf(" diff = %20.14g\n", diff);
double xo = 1.0 / (molecWeight/1000. * 2 * m + 1.0);
printf(" no = %g\n", xo);
double tmp = diff / RT;
double actCoefWater = exp(tmp) / xo;
printf("actCoefWater = %g\n", actCoefWater);
}
int main()
{
printf("standalone test of Gibbs excess free energy:\n");
printf("T = 50C\n");
double Iionic = 6.146;
printf("Ionic Strength = %g\n", Iionic);
calc(273.15 + 50., Iionic);
printf("T = 200C\n");
calc(273.15 + 200., Iionic);
return 0;
}