Problems 407b. A harmonic oscillator of frequencyωinddimensions has energy eigen-
values given by
En=(
n+d
2)
̄hω,but the energy levels become degenerate. The degeneracy of each level isg(En) =
(n+d−1)!
n!(d−1)!.
Calculate the canonical partition function, free energy, total energy, and
heat capacity in this case.10.6. The Hamiltonian for a free particle in one dimension is
Hˆ= pˆ2
2 m.
a. Using the free particle eigenfunctions, show that the canonicaldensity
matrix is given by〈x|e−β
Hˆ
|x′〉=(
m
2 πβ ̄h^2) 1 / 2
exp[
−
m
2 β ̄h^2(x−x′)
2]
b. Recall that an operatorAˆin the Heisenberg picture evolves in time ac-
cording to
Aˆ(t) = eiHˆt/ ̄hAˆe−iHˆt/ ̄h.
Now consider a transformation from real timetto an imaginary time
variableτviat=−iτ ̄h. In imaginary time, the evolution of an operator
becomes
Aˆ(τ) = eτHˆAˆe−τHˆ
Using this evolution, derive an expression for the imaginary-time mean-
square displacement of a free particle defined to be
R^2 (τ) =〈[ˆx(0)−xˆ(τ)]^2 〉.
Assume the particle is a one-dimensional box of lengthL. This function
can be used to quantify the quantum delocalization of a particle at tem-
peratureT.10.7. The following theorem is due to Peierls (1938): Let{|φn〉}be an arbitrary set
of orthonormal functions on the Hilbert space of a quantum system whose
Hamiltonian isHˆ. The functions{|φn〉}are assumed to satisfy the same
boundary and symmetry conditions of the physical system. It follows that
the canonical partition functionQ(N,V,T) satisfies the inequality
Q(N,V,T)≥∑
ne−β〈φn|
Hˆ|φn〉
,where equality holds only if{|φn〉}are the eigenfunctions ofHˆ. Prove this
theorem.