214 Canonical ensemble
4.10. The canonical ensemble version of the classical virial theoremis credited to
Richard C. Tolman (1918). Prove that the canonical average
〈
xi∂H
∂xj〉
=
1
N!h^3 NQ(N,V,T)∫
dxxi∂H
∂xj
e−βH(x)=kTδijholds. What assumptions must be made in the derivation of this result?4.11. Prove that the structure factorS(q) of a one-component isotropic liquid or
gas is related to the radial distribution functiong(r) via eqn. (4.6.31).4.12. Consider a system ofN identical noninteracting molecules, each molecule
being comprised ofn atoms with some chemical bonding pattern within
the molecule. The atoms in each molecule are held together by a potential
u(r
(i)
1 ,...,r(i)
n),i= 1,...,N, which rapidly increases as the distance between
any two pairs of atoms increases, and becomes infinite as the distance be-
tween any two atoms in the molecule becomes infinite. Assume the atoms in
each molecule have massesmk, wherek= 1,...,n.a. Write down the Hamiltonian and the canonical partition function for this
system and show that the partition function can be reduced to a product
of single-molecule partition functions.b. Make the following change of coordinates in your single-molecule partition
function:s 1 =1
M
∑nk=1mkrksk=rk−1
m′kk∑− 1l=1mlrl k= 2,...,n,wherem′k≡k∑− 1l=1ml,Mis the total mass of a molecule, and theisuperscript has been dropped
for simplicity. What is the meaning of the coordinates 1? Show that if
u(r 1 ,...,rn) only depends on therelativecoordinates between pairs of
atoms in the molecule, then single molecule partition function is of the
general form
Q(N,V,T) =(V f(n,T))N
N!,
wheref(n,T) is a pure function ofnandT.c. Show, therefore, that the equation of state isalwaysthat of an ideal gas,
independent of the type of molecule in the system.