Lamellar Stack Paracrystal - lamellar_stack_paracrystal.c
/* Lamellar_ParaCrystal - Pedersen's model
*/
double paraCryst_sn(double ww, double qval, double davg, int Nlayers, double an);
double paraCryst_an(double ww, double qval, double davg, int Nlayers);
static double
Iq(double qval,
double th,
double fp_Nlayers,
double davg,
double pd,
double sld,
double solvent_sld)
{
//get the fractional part of Nlayers, to determine the "mixing" of N's
int n1 = (int)(fp_Nlayers); //truncate towards zero
int n2 = n1 + 1;
const double xn = (double)n2 - fp_Nlayers; //fractional contribution of n1
const double ww = exp(-0.5*square(qval*pd*davg));
//calculate the n1 contribution
double Znq,Snq,an;
an = paraCryst_an(ww,qval,davg,n1);
Snq = paraCryst_sn(ww,qval,davg,n1,an);
Znq = xn*Snq;
//calculate the n2 contribution
an = paraCryst_an(ww,qval,davg,n2);
Snq = paraCryst_sn(ww,qval,davg,n2,an);
Znq += (1.0-xn)*Snq;
//and the independent contribution
Znq += (1.0-ww*ww)/(1.0+ww*ww-2.0*ww*cos(qval*davg));
//the limit when Nlayers approaches infinity
// Zq = (1-ww^2)/(1+ww^2-2*ww*cos(qval*davg))
const double xi = th/2.0; //use 1/2 the bilayer thickness
const double Pbil = square(sas_sinx_x(qval*xi));
const double contr = sld - solvent_sld;
const double inten = 2.0*M_PI*contr*contr*Pbil*Znq/(qval*qval);
//printf("q=%.7e wwm1=%g ww=%.5e an=% 12.5e Snq=% 12.5e Znq=% 12.5e Pbil=% 12.5e\n",qval,wwm1,ww,an,Snq,Znq,Pbil);
return 1.0e-4*inten;
}
// functions for the lamellar paracrystal model
double
paraCryst_sn(double ww, double qval, double davg, int Nlayers, double an) {
double Snq;
Snq = an/( (double)Nlayers*square(1.0+ww*ww-2.0*ww*cos(qval*davg)) );
return Snq;
}
double
paraCryst_an(double ww, double qval, double davg, int Nlayers) {
double an;
an = 4.0*ww*ww - 2.0*(ww*ww*ww+ww)*cos(qval*davg);
an -= 4.0*pow(ww,(Nlayers+2))*cos((double)Nlayers*qval*davg);
an += 2.0*pow(ww,(Nlayers+3))*cos((double)(Nlayers-1)*qval*davg);
an += 2.0*pow(ww,(Nlayers+1))*cos((double)(Nlayers+1)*qval*davg);
return an;
}
Back to Model
Download