Thank you very much for the lecture! I have a question regarding the difference in free energy between two states "a" and "b": I've frequently found in textbooks and papers that one possible way of obtaining this value is by calculating it as dA = -kT*ln(Pa/Pb), where Pi is the probability of finding your system in the state "i", which could in principle be readily computed (assuming a simple system with enough sampling) by the number of conformations found in each state during a molecular dynamics simulation. Considering that the free energy doesn't depend on the probability of a specific microstate and actually depends on the partition function itself (which is constant for a given system, so Qa=Qb=Q), how come this computation is correct? I mean, wouldn't the equation A = -kT*ln(Q) imply that there isn't such a thing as a difference in free energy between two microstates from the same macrostate (for instance two different conformations of a molecule)? Or is it the case that when we compute these differences we actually assume that each conformation (a and b) represents their own macrostate (thus Qa =/= Qb) instead of being a microstate from the same system? Thank you very much for your time, sorry for the long question! I'd really appreciate it if you could suggest to me a book where I can find more on this subject as well, I haven't been able to find this discussion.

why is helmholtz and gibbs energy called free energy?