1134 27 Equilibrium Statistical Mechanics. III. Ensembles
to the flow of a compressible fluid in ordinary space and is governed by an equation
called the Liouville equation,^1 which is valid both for an equilibrium system and a
nonequilibrium system.
We consider only the equilibrium case so that the distribution of these points’ phase
space is time-independent. In quantum statistical mechanics, we had a discrete list of
possible states. In classical statistical mechanics, we have coordinates and momentum
components that can range continuously. We denote the probability distribution (prob-
ability density) for the ensemble byfand define the probability that the phase point
of a randomly selected system of the ensemble will lie in the 6N-dimensional volume
elementd^3 r 1 d^3 p 1 d^3 r 2 d^3 p 2 ···d^3 rNd^3 pNto be
Probabilityf(r 1 ,p 1 ,r 2 ,p 2 ,...rN,pN)d^3 r 1 d^3 p 1 d^3 r 2 d^3 p 2 ···d^3 rNd^3 pN
f(q,p)dqdp (27.4-1)
whered^3 r 1 stands fordx 1 dy 1 dz 1 ,d^3 p 1 stands fordpx 1 dpy 1 dpz 1 , and so forth, where
qstands for all of the coordinates,pstands for all of the momentum components, and
wheredqdpstands for the entire volume elementd^3 r 1 d^3 p 1 d^3 r 2 d^3 p 2 ···d^3 rNd^3 pN.
Classical mechanical formulas must agree with those obtained by taking the limit
of quantum mechanical formulas as masses and energies become large (thecorre-
spondence limit). This limit does not affect the formula representing the equilibrium
canonical probability density, so it must therefore be the same function of the energy as
that of quantum statistical mechanics. For a one-component monatomic gas or liquid
ofNmolecules without electronic excitation but with intermolecular forces, the clas-
sical energy (classical Hamiltonian functionH) is expressed in terms of momentum
components and coordinates:
HH(p,q)K +V
1
2 m
∑N
i 1
(p^2 xi+p^2 yi+p^2 zi)+V(q) (27.4-2)
whereK is the kinetic energy andVis the potential energy of the system.
By analogy with Eq. (27.1-34), the normalized canonical probability density is
ff(p,q)f(H)
1
Zcl
e−H(p,q)/kBT (27.4-3)
whereZclis called theclassical canonical partition functionor the classicalphase
integral:
Zcl
∫∫
···
∫
e−H(p,q)/kBTd^3 r 1 d^3 r 2 d^3 r 3 ...d^3 rNd^3 p 1 d^3 p 2 ...d^3 pN
∫
e−H(p,q)/kBTdqdp (27.4-4)
If the system is in a container, the coordinate integrations in this formula range over all
values of the coordinates inside the container, and the momentum integrations range
from negative infinity to positive infinity. Since our theory is nonrelativistic, there is
no limitation on the speeds of the particles.
(^1) D. A. McQuarrie,Statistical Mechanics, Harper & Row, New York, 1976, p. 119ff.