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Gerry and Knight solution to single-mode Maxwell equation

Дата публикации: 08-07-2026 21:29:44



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TL;DR
I have two questions concerning treatment of the single-mode solution to Maxwell's equation presented in Gerry and Knight's. Namely, where does the expression for the amplitude of the electric field comes from, and secondly how did they handle the integral over dV in the classical E-M Hamiltonian that contains the V^-1 term, without it blowing up.

In the book, they present the solution to the maxwell equation for a wave propagating in 1-D. My only issue is determining where the specific expression for the amplitude of the electric field comes from. Their solution is:

Screenshot 2026-07-08 at 11.04.53 AM.webp

Even if we use the classical energy in the field and equate it to the single-photon energy (ignoring zero point) as such:

Screenshot 2026-07-08 at 11.05.44 AM.webp

we'd get 𝜔 inside the parentheses not 𝜔^2? Can someone help shed some light please?

Secondly, when we go from:

Screenshot 2026-07-08 at 11.06.59 AM.webp

to:

Screenshot 2026-07-08 at 11.07.02 AM.webp

I understand what they are trying to get, the only thing that trips me up is I don't see how they handled the integral, seeing that you have to integrate over d𝑉/𝑉 because of the coefficient in front (mentioned above in the amplitude ). What am I missing please?

Thank you!

I'll try to answer as best I can.

For the first part, the "missing ω" is effectively hidden inside the definition of q(t). In the quantized theory,
##
q=\sqrt{\frac{\hbar}{2\omega}}(a+a^\dagger),
##
so q already contains a factor ##1/\sqrt{\omega}##.

For the second part, it seems to me that the notation is somewhat unfortunate because the same symbol V is used both for the total volume and in ##dV## for the volume element. Then the factor ##1/V## is not problematic because V is the total cavity (quantization) volume, i.e. a constant, not the integration variable. More explicitly, one could write the quantization volume as ##\mathcal V##, so that
##
\int_{\mathcal V}\frac{dV}{\mathcal V}
=
\frac{1}{\mathcal V}\int_{\mathcal V} dV
=
1.
##
Also, if I'm not mistaken, for the cavity mode
##
\int_V \sin^2(kz)\,dV = \frac{V}{2},
##
which exactly cancels the explicit ##1/V## factor in the field normalization.

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