1122 27 Equilibrium Statistical Mechanics. III. Ensembles
27.1 The Canonical Ensemble
In Chapters 25 and 26 we applied statistical mechanics to dilute gases, based on
the probability distribution for states of molecules in a dilute gas with fixed energy,
fixed volume, and fixed number of molecules. This chapter presents an alternative
approach to statistical mechanics, which is in principle applicable to any kind of a
system. It is based on the concept of anensemble, which is an imaginary collection
of very many replicas of the real system. Each replica occupies the same macrostate
as the real system, but different members of the ensemble occupy different system
microstates.
If the equilibrium macrostate of a closed system is specified by fixed values of the
thermodynamic energyU, the volumeV, and number of moleculesN,amicrocanonical
ensembleis used to represent it. The systems of this ensemble have the same values of
E(withEequal toU),N, andVbut occupy different microstates. Our discussion in
Chapters 25 and 26 is equivalent to using the microcanonical ensemble to represent a
dilute gas.
Thecanonical ensemblerepresents a closed system at equilibrium with a macrostate
specified by values ofT,V, andN. The systems of the canonical ensemble are placed
in thermal contact with each other so that each system of the ensemble is in a constant-
temperature bath consisting of the other systems of the ensemble, and all have the same
temperature. Figure 27.1 schematically depicts a portion of such an ensemble.
One system with given
values of N,V, and T
Figure 27.1 A Canonical Ensemble.
Thegrandcanonicalensemblerepresents an open system with a macrostate specified
by values ofT,V, andμ(the chemical potential) for each substance present. Each
system of the ensemble is open to the other systems of the ensemble and can exchange
matter and energy with the other systems. Discussions of the grand canonical ensemble
can be found in statistical mechanics textbooks, but we will not discuss it.
The Postulates of Statistical Mechanics
The two postulates of equilibrium statistical mechanics introduced in Chapter 25 can
now be restated:
Postulate 1. Observed values of thermodynamic variables in the actual system can be
represented by ensemble averages of the corresponding mechanical variables.
Postulate 2. In any ensemble, each system microstate corresponding to the same values
ofE,V, andNis occupied by an equal number of systems.
The Canonical Probability Distribution
Imagine that the Schrödinger equation of the real system has been solved, and that
we have a list of its very many system energy eigenfunctions and energy eigenvalues,
each corresponding to the same volume and same number of molecules. The fact that
we cannot actually carry out this solution is unimportant until we attempt to carry out
calculations. The energy eigenfunctions are numberedΨ 1 ,Ψ 2 ,Ψ 3 , and so on, with
energy eigenvaluesE 1 ,E 2 ,E 3 , and so on. Although there are infinitely many such
states, we imagine that the ensemble contains so many systems that each of these
system states is occupied by some members of the ensemble. Letn 1 be the number of
systems in the ensemble that are in system state 1,n 2 be the number of systems in system