mildly relativistic
e- • --------------------------------------
|
| q virtual photon
|
/ \ k + q virtual electron-
\ / positron pair e- e+
|
| q virtual photon
|
● ---------------------------------------
e+ static
Let us analyze purely classical waves which interact. The electron and the positron are presented as waves in the Dirac field. These waves meet each other.
There is an interaction between the electromagnetic field and the Dirac field.
The waves disturb the electromagnetic field, causing waves there. The waves in the electromagnetic field, in turn, disturb the Dirac field.
The vacuum polarization loop is the disturbance in the Dirac field.
If these all are classical waves, then there cannot be any divergence. A divergence would break conservation of energy.
Deep question. Do the quantum waves in the physical world, also in a Feynman diagram, behave like classical waves, or can they behave like in the Feynman integrals, where divergences occur?
If the answer to the question is that the waves must behave like classical waves, then we have a solution to the divergence problem of QED: there is no divergence if the calculations are done in the classical way.
Photon versus a laser beam. A laser beam is a classical wave. A photon behaves just like a laser beam until we measure the photon, and the wave "collapses". That is, a photon must be described as a classical wave until the measurement. Does the same hold for any intermediate state of a Feynman diagram, until the outgoing particles are measured?
Divergences are a result of "breaking into more degrees of freedom"
If one interprets the diagram above as a Feynman diagram, then the phase of the outgoing waves is not affected by k at all. There is a constructive interference for all k. This leads to the notorious divergence problem.
The divergence of the vacuum polarization loop happens when the system "breaks into more degrees of freedom". The value of the the 4-momentum k can be chosen freely – it is a new degree of freedom.
Classical waves also can break into more degrees of freedom. But for them, this does not create any divergences. Why?
The obvious answer is that destructive interference wipes out any classical waves which have high momenta k (short wavelength). If a wave is wiped out, then it cannot pass a disturbance forward.
A classical analogue of the vacuum polarization loop
Let us have two elastic metal plates. They correspond to the electron and the positron in the loop.
Let us model the electromagnetic wave with a wave propagating in a rubber membrane. The rubber membrane is somehow loosely attached to the plates, maybe via very elastic rubber blocks. This constitutes the interaction.
metal plate (e+)
------------------
interaction
/\/\/\/\/\/\/\/\/\/\/\ rubber membrane
interaction
------------------ (e-)
metal plate
--> wave propagation direction
As the rubber wave meets the plates, it interacts with them and creates waves into the plates. Later, these created waves can be absorbed back into the rubber membrane.
Does this mean that the rubber wave "breaks into more degrees of freedom"?
We can model the interaction by assuming that each small area element of the rubber membrane hits with a "sharp hammer" both metal plates. This is the Green's function approach to analyze the process.
The impulse from the sharp hammer generates waves of varying momenta k. There is no limit on how large |k| can be.
Let us analyze different momenta. Does it make sense that the e+ plate receives k and the e- plate -k? If the rubber wave pushes the plates apart (like an electric field pushes e+ and e- apart), then this assumption is reasonable. An area element of the rubber membrane hits both plates with a sharp hammer: one upward and the other downward.
Later, the process can happen time-reversed: the rubber membrane absorbs some waves from the plates.
We seem to have a process analogous to what happens in the Feynman diagram vacuum polarization loop. We can freely choose k, and it will contribute to the waves absorbed back into the rubber membrane.
Why does this not lead to a divergence in the classical system?
One aspect is conservation of energy. Hitting with an infinitely sharp hammer would consume an infinite amount of energy? Then all hits must be done with a "blunt hammer". Destructive interference wipes away all high |k|.
Why should Feynman diagrams allow a sharp hammer? Why not require a blunt hammer?
The vertex correction: the infrared divergence with small |k|
Another loop in a Feynman diagram appears in the vertex correction of QED. Again, the system "breaks into more degrees of freedom", because of the loop. Let us try to find a classical counterpart.
^
\ p + q
\
\
| \
| \ p - k + q
k | |-----------------● Z+ nucleus
| / q
| / p - k
/
/
/
e-
p
The electron e- bumps from the nucleus Z+. The momentum exchange is q. The electron sends to itself a virtual photon whose 4-momentum is k.
We can choose k freely. This causes a divergence in the Feynman integral for small |k|.
There is a direct classical analogue of this process. If we model the electric field of the electron with an elastic block of rubber attached to the electron, then the momentum exchange q makes the rubber to "wobble". The electron gives some momentum k and kinetic energy to the rubber block, and absorbs some of k back when the electron leaves the nucleus.
We already analyzed this in our post on September 24, 2025. The Feynman integral method does not understand the fact that an infinite number of "soft" real photons, or virtual photons with small |k|, are produced when the classical electron passes once by the classical nucleus. The integral thinks that these are all separate cases. The integral diverges to infinity because it thinks that the cases are separate, while they are not.
We see that the "break into more degrees of freedom" is the infrared case causes a divergence problem which is quite different from the ultraviolet case (vacuum polarization).
Further analysis of the classical vacuum polarization analogue
The metal plate analogue above is awkward. Very different from any "polarization". What about assuming a polarizable medium? When a classical electromagnetic field meets that medium, it produces a "polarization wave".
/\/\/\/\/\ ############
--->
electromagnetic polarizable medium
wave
We might have two charged fields. One would have a uniform positive charge density, and the other the canceling negative charge density. These two classical fields would correspond to the Dirac field.
The classical analysis is similar to our rubber membrane - metal plate model. Since the incoming wave is smooth, destructive interference cancels all high momenta |k|.
Quantum mechanics: the interference pattern of two created particles
We have tackled with this question many times in the past few years. Suppose that two waves are born simultaneously: e+ and e-.
For classical fields, it is enough that destructive interference cancels the waves e+ and e- separately. But in quantum mechanics, the waves are entangled. How does destructive interference act on them?
*** WORK IN PROGRESS ***






