These results are quite interesting, as one can see that the entropy changes slope at the phase transition
(fig. 143) and the specific heat is linear in temperature but exhibits a discontinuity atTC(fig. 144).
(These figures originally belong to a calculation about superconductivity, but they also hold true
for our computations. The indexnstands for "‘normal"’ andsfor "‘superconducting"’, which is the
material that undergoes the phase transition).
Figure 143: The entropy as a function of temperatureFigure 144: The specific heat as a function of temperatureWe now want to take our calculations even further and include a magnetic fieldB, so the formula for
the free energy becomes:
f=f 0 +α 0 (T−TC)m^2 +1
2
βm^4 −mB (260)By minimizing the free energy as before, one is left with an expression for small values of the order
parametermatT > TC, which looks similar to the Curie-Weiss law:
m=B
2 α 0 (T−TC)