A Short Course on Quantum Mechanics and Methods of Quantization 43Recalling that (i) the classical action is given by:
S=
∫t0dt′m
2(
dx
dt) 2
(1.208)
and (ii) the solution of the classical equation of motiond^2 x(t)/dt^2 = 0, satisfying
the boundary conditionsx(0) =x′,x(t)=x, yields the classical trajectory:
xcl(t′)=t′(x−x′)
t+x′, x ̇cl(t′)=x−x′
t, (1.209)
one can easily verify that:
Sclas(x, x′)≡S|xcl=∫t0dt′m
2(
x−x′
t′) 2
. (1.210)
Comparing with (1.207), we see that the quantum kernel is given by the exponen-
tial of the classical action:
〈x|e−ıtH|x′〉=F(t)exp[ı
Sclas(x, x′)]
,F(t)=√
m
2 πit. (1.211)
up to a pre-factorF(t) which depends only on time. It is an interesting fact that
it can be calculated exactly by also makinguse of a semi-classical stationary phase
approximation[ 35 ].
Example 1.3.3. The 1D harmonic oscillator.
Similar calculations can be done for the Hamiltonian of the 1D harmonic oscillator,
to get:
K(x, x′;t)=Fho(t)exp[ı
Sclas(x, x′)]
, (1.212)
with
Scl(x, x′)=ωm
2 sin(ωt)[
(x+x′)^2 cos(ωt)− 2 xx′]
, (1.213)
Fho=√
mω
2 πısin(ωt). (1.214)As in the previous example,Fhocan be calculated exactly by means of the sta-
tionary phase approximation[ 35 ].
1.3.2.2 Feynman integral in imaginary time and partition function
For a quantum system, the (canonical) partition function can be calculated as:
Z≡Tr[
e−βH]
=
∫
dx〈x|e−βH|x〉. (1.215)