130_notes.dvi

(Frankie) #1

We will now study the radiation field in a region with no sources so that∇·~ A~= 0. We will use the
equations


B~ = ∇×~ A~

E~ = −^1
c

∂A~

∂t

∇^2 A~−

1

c^2

∂A~

∂t^2

= 0

33.2 Fourier Decomposition of Radiation Oscillators


Our goal is to write the Hamiltonian for the radiation field in terms of a sum of harmonic oscillator
Hamiltonians. The first step is to write the radiation field in as simple a way as possible, as a sum
of harmonic components. We will work in a cubic volumeV=L^3 and applyperiodic boundary
conditionson our electromagnetic waves. We also assume for now that there areno sources inside
the regionso that we can make a gauge transformation to makeA 0 = 0 and hence∇·~ A~= 0. We
decompose the field into its Fourier componentsatt= 0


A~(~x,t= 0) =√^1
V


k

∑^2

α=1

ˆǫ(α)

(

ck,α(t= 0)ei
~k·~x
+c∗k,α(t= 0)e−i
~k·~x)

where ˆǫ(α) are real unit vectors, andck,αis the coefficient of the wave with wave vector~kand
polarization vector ˆǫ(α). Once the wave vector is chosen, the two polarization vectors must be
picked so that ˆǫ(1), ˆǫ(2), and~kform a right handed orthogonal system. The components of
the wave vector must satisfy


ki=
2 πni
L

due to the periodic boundary conditions. The factor out front is set to normalize the states nicely
since
1
V



d^3 xei
~k·~x
e−i
~k′·~x
=δ~k~k′

and
ˆǫ(α)·ˆǫ(α


′)
=δαα′.

We know thetime dependence of the wavesfrom Maxwell’s equation,


ck,α(t) =ck,α(0)e−iωt

whereω=kc. We can now write thevector potential as a function of position and time.


A~(~x,t) =√^1
V


k

∑^2

α=1

ǫˆ(α)

(

ck,α(t)ei
~k·~x
+c∗k,α(t)e−i
~k·~x)

We may write this solution in several different ways, and use the bestone for the calculation being
performed. One nice way to write this is in terms 4-vectorkμ, the wave number,


kμ=


̄h

= (kx,ky,kz,ik) = (kx,ky,kz,i

ω
c

)
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