Exercises 533
(b) Now consider the integralI 2 =∫
dx 1 dx 1 ∗...dxNdxN∗e−x
†Axwherexis now a complex vector. Show thatI 2 =
( 2 π)N
det(A)
.15.2 In this problem and the next we take a closer look at the free field theory. Consider
the one-dimensional, periodic chain of particles with harmonic coupling between
nearest neighbours, and moving in a harmonic potential with coupling constantm^2.
The Lagrangian is given by
L=
1
2∑∞
n=−∞[φ ̇n^2 −(φn−φn+ 1 )^2 −m^2 φn^2 ].We want to find the HamiltonianHsuch that
∫
[Dφn]e−S=〈i|e−(tf−ti)H|f〉where
S=∫tftiL[φn(t)]dtand the path integral∫
[Dφn]is over all field configurations{φn}compatible withi
attiandfattf.
We use the Fourier transformsφk=∑
nφneikn; φn=∫ 2 π0dk
2 π
φke−ikn.(a) Show that from the fact thatφnis real, it follows thatφk=φ∗−k, and that the
Lagrangian can be written asL=
1
2∫ 2 π0dk
2 π
{|φ ̇k|^2 −φ−k[m^2 + 2 ( 1 −cosk)]φk}.This can be viewed as a set of uncoupled harmonic oscillators with coupling
constantω^2 k=m^2 + 2 ( 1 −cosk).
(b) In Section 12.4 we have evaluated the Hamiltonian for a harmonic oscillator. Use
the result obtained there to findH=
1
2∫ 2 π0dk
2 π
{ˆπ(k)π(ˆ −k)+φ(ˆ−k)[m^2 + 2 ( 1 −cosk)]φ(ˆk)},where the hats denote operators;π(ˆ k)is the momentum operator conjugate to
φ(ˆk)– they satisfy the commutation relation
[ˆπ(k),φ(ˆ−k′)]=i∑
neik(k−k′)n= 2 πδ(k−k′),where the argument of the delta-function should be taken modulo 2π.