I didn't bother draw the other 3 lines, but you just ned to make the necessary changes to gamma for that.
If you run something like what you had originally, you only want the fist point of f''().
Pr=6.2; G=0.1;
phi=0.0;
rhof=997.1;Cpf=4179;kf=0.613;
rhos=6320;Cps=531.8;ks=76.5;
a1=((1-phi)^2.5)*(1-phi+phi*(rhos/rhof));
a2=(1-phi+phi*((rhos*Cps)/(rhof*Cpf)));
A=(ks+2*kf+phi*(kf-ks))/(ks+2*kf-2*phi*(kf-ks));
BCres= @(ya,yb) ...
[ya(1); ya(2)-1-G*ya(3); ya(4)-1; yb(2); yb(4)];
fODE = @(x,y) ...
[y(2); y(3); a1*(y(2)^2-y(3)*y(1)); y(5); -A*Pr*a2*y(1)*y(5)];
xa=0;xb=8;
solinit=bvpinit(linspace(xa,xb,101),[0 1 0 1 0]);
sol=bvp4c(fODE,BCres,solinit);
xint=linspace(xa,xb,101);
sxint=deval(sol,xint);
figure(1)
plot(xint,(1-phi)^-2.5*sxint(3,:),'-','Linewidth',1.5);
xlabel('\eta');
ylabel('f''(0)/(1-phi)^2.5');
Now you have to re-run the above, but change phi over the range given in the Fig.
xa=0;xb=8;
phiv = [0:0.04:0.2]';
p = [];
for i=1:length(phiv)
phi = phiv(i);
a1=((1-phi)^2.5)*(1-phi+phi*(rhos/rhof));
a2=(1-phi+phi*((rhos*Cps)/(rhof*Cpf)));
A=(ks+2*kf+phi*(kf-ks))/(ks+2*kf-2*phi*(kf-ks));
fODE = @(x,y) ...
[y(2); y(3); a1*(y(2)^2-y(3)*y(1)); y(5); -A*Pr*a2*y(1)*y(5)];
solinit=bvpinit(linspace(xa,xb,101),[0 1 0 1 0]);
sol=bvp4c(fODE,BCres,solinit);
p(i,1) = (1-phi)^-2.5*sxint(3,1)
end
plot(phiv, p,'o-')
xlabel('\phi'); ylabel('f''''(0) & stuff')
Resultant plot is as above.
Best Answer