456 The Feynman path integral
xImaginary time0 ℏ/2 ℏ
xβ βFig. 12.7 Representative paths in the discrete path sum for the canonical partition function.
be expressed compactly as the limit of an expression that resemblesa classical config-
urational partition function
Q(L,T) = lim
P→∞(
mP
2 πβ ̄h^2)P/ 2 ∫
D(L)dx 1 ···dxPe−βφ(x^1 ,...,xP), (12.2.27)an analogy we will revisit when we discuss numerical methods for evaluating path
integrals in Section 12.6. Here,
φ(x 1 ,...,xP) =∑P
k=1[
1
2
mωP^2 (xk−xk+1)^2 +1
P
U(xk)]
, (12.2.28)
whereωP=
√
P/β ̄handxP+1=x 1.
An analytical calculation of the density matrix, partition function, or propagator
via path integration proceeds first by carrying out theP-dimensional integration and
then taking the limit of the result asP → ∞. As a simple example, consider the
density matrix for a free particle (U(x) = 0). Assumex∈(−∞,∞). The density
matrix in this case is given by
ρ(x,x′;β) = lim
P→∞(
mP
2 πβ ̄h^2)P/ 2
×
∫
dx 2 ···dxPexp{
−
∑P
k=1[
mP
2 β ̄h^2(xk+1−xk)^2]}∣∣
∣
∣
∣
xP+1=x′x 1 =x. (12.2.29)
In fact, we previously solved this problem in Section 4.5. Eqn. (4.5.33)is the partition
function for a classical polymer with harmonic nearest-neighbor particle couplings and
fixed endpoints. Applying the result of eqn. (4.5.33) to eqn. (12.2.29), recognizing the