c08 JWBS043-Rogers September 13, 2010 11:25 Printer Name: Yet to Come
112 A STATISTICAL APPROACH TO THERMODYNAMICS8.3 GIBBS FREE ENERGY AND THE PARTITION FUNCTION
Taking logarithms of the previous equation, we obtainlnKeq=−ε 0
RT+lnQB
QA
whereε 0 =εB 0 −εA 0. Multiplying by−RT, we get−RTlnKeq=ε 0 −RTlnQB
QA
but−RTlnKeq=G◦,soG◦=ε 0 −RTlnQB
QA
Comparing this equation with the definition of the Gibbs chemical potential
G◦≡H◦−TS◦, we see that the classical enthalpy changeH◦for a re-
action is largely controlled by the energy separating the ground statesε 0 , and the
entropy changeTS◦is largely controlled by the ratio of the multiplicity of levels
available in each stateRTln (QB/QA). In very many cases, the enthalpy change is
dominant in chemical reactions, which explains why some very good nineteenth-
century scientists thought thatH◦was the only factor controlling equilibrium and
reaction spontaneity.
Given that reactions and physical processes exist that are not solely controlled or
dominated by the enthalpy change, it is the ratio of partition functions that interests
us. The partition function gives us the distribution of molecules over the energy levels
within a state. We may think of these asmicrostateswithin a state. If the enthalpy
balance is close, the reaction tends to go in the direction with the most microstates.
Such a reaction or process is maximizing the number of choices a particle (molecule)
has in which to reside within a state. A system providing a maximum number of
choices provides the maximum disorder, just as the number of places youmayfind
that piece of paper you are looking for is determined by the disorder of the desktop.
A disordered desktop has more microstates than an orderly one.
Looking again at the equationG◦=ε 0 −RTln (QB/QA), we can see another
reason why thermodynamicists prior to Gibbs could have missed the importance of
entropy in equilibrium. The second term includesT, so it may be small at ordinary
temperatures. The ratio of microstatesQB/QAmay be negligible at lower tempera-
tures, but it becomes important at higher temperatures and it may favor or disfavor
the product side of the equilibrium according to which is larger,QAorQB.Asis
true in classical thermodynamics, there are four possibilities for the two terms in
G◦=ε 0 −RTln (QB/QA): They may be FF, FD, DF, or DD, where F denotes
a term that favors the product side of the equilibrium and D denotes a term that
disfavors the product side.