Classical limit of Quantum Optics

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SUMMARY

The discussion centers on the classical limit of quantum optics, specifically addressing the nature of photon wavefunctions and their relationship to electromagnetic fields. It establishes that quantum electrodynamics (QED) remains unrefuted and serves as a foundational model in physics. The conversation highlights the transformation of electromagnetic fields into quantized states, where each oscillator corresponds to a photon. Key questions arise regarding the appearance of photon wavefunctions and their combination to form observable wave packets.

PREREQUISITES
  • Quantum Electrodynamics (QED) fundamentals
  • Wave-particle duality in quantum mechanics
  • Fourier transforms in wave analysis
  • Electromagnetic field theory
NEXT STEPS
  • Study the mathematical formulation of Quantum Electrodynamics (QED)
  • Explore the concept of wavefunction in quantum mechanics
  • Investigate the relationship between wave packets and photon wavefunctions
  • Learn about the quantization of electromagnetic fields and its implications
USEFUL FOR

Physicists, quantum mechanics students, and researchers in quantum optics seeking to deepen their understanding of photon behavior and the principles of quantum electrodynamics.

Xian
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I don't profess of a knowledge of QED, and am in fact incredibly ignorant of its formulation and nuances, however I do understand that its never been refuted and is the crown jewel of physical models. So I will take it as fact for this post.

What confuses me, is that in quantum mechanics, every particle must be described by a wavefunction which is a complete characterization of its state. So it follows that a photon has a wavefunction.

Classically, when we observe light, we are told that we measure an undulatory wave packet of some local frequency ω. When we look at the Fourier transform of the wave packet we get peaks at the frequencies ω and -ω and the rest of the constituent frequencies clump around it (due to the fact that bounded wave packets must be built from a continuum of waves).

If this is indeed what is measured, how do the photon wavefunctions combine to create such an elegant waveform?
What does a photon wave function look like?
And where do E-fields and B-fields come in for the single photon case?
 
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In QED it works the other way around. You start from the electromagnetic field. Then you treat waves of each wavelength as independent harmonic oscillators. By applying quantum mechanics, we find that each oscillator has a discrete set of energy states, and the difference between any two consecutive energy levels is Planck's constant times the frequency of light at that wavelength. When one of the oscillators is in the first energy level above its ground state, that means there is one photon.
 
Hmm, so in essence QED quantizes the field? And when this quantization is done, we identify excited states with photons?

A related question then is what do the photon wavefunctions look like?
 

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