Why can't a spin 0 graviton couple to a photon? [closed]

I read that a spin 0 graviton can't couple to traceless energy, such as a photon, in the introduction in the book The Feynman Lectures On Gravitation. Why is this true? What does it mean for a particle's energy to be "traceless"?

This has been my reference all along.

A spin 0 graviton can only couple to the trace of energy, and not to traceless energy.

• can you give a link for your assertions about trace and traceless? and quantizing Newton's gravity? – anna v Apr 23 '18 at 19:10
• This doesn't make sense. Newtonian gravity isn't a field theory, so there is no wave equation to quantize. – Ben Crowell Apr 23 '18 at 19:55
• Newtonian gravity has all the book-keeping of a field theory within it. It is a field theory, and if you retard the speed of gravity to the speed of light, then you do get gravity waves predicted. All that is needed to predict waves is speed retardation. – New guy Apr 25 '18 at 17:40
• I can't give a specific link. However, any number of books say that a spin O graviton is the simplest type of graviton, and you get it if you quantize Newton's theory. For example, Paul Davies's "Superforce" and "Forces " popular books. – New guy Apr 25 '18 at 17:47
• Why do you keep writing the letter Oh instead of the number zero for spin? – Qmechanic Apr 27 '18 at 17:46

You manifestly have a metric tnesor in the equation of motion for photons, and a spacetime containing photons manifestly has a nonzero stress-energy tensor, so you don't have to do any spin gynmastics to couple photons to gravitons, it's already there in the classical theory before you even quantize.

• I don't understand your answer. It seems to me to apply to General Relativity, and not answer my question. - I would have edited my original question, but it had already received two responses. – New guy Apr 24 '18 at 16:01
• @Newguy: you can't have Newtonian gravity coexisting with electromagnetism. Newtonian gravity is inconsistent with special relativity, but Maxwell theory requires special relativity. – Jerry Schirmer Apr 24 '18 at 16:45
• I'm not talking about classical Newtonian gravity. I'm asking about a zero-rest mass, traceless, moving at light-speed -- therefore consistent with special relativity -- spin O graviton. Why can't it couple to the traceless energy of a photon? – New guy Apr 24 '18 at 17:41
• @Newguy: isn't the only renormalizable coupling between a scalar field and a vector field the one you get from the $D_{\mu}\phi^{*}D^{\mu}\phi$ term in the scalar QED Lagrangian, which would require your spin 0 graviton to have charge? – Jerry Schirmer Apr 24 '18 at 19:54
• I do not know. It is nothing to do with my question. – New guy Apr 25 '18 at 17:18

The answer of Bob Bee here discusses zero spin gravitons.

Going into quantum field theories, one has to define the number of forces one is going to unite, and the couplings and gauge bosons , i.e. the force carriers. Whether there is a coupling between a photon, the gauge boson for the electromagnetic interaction, and the graviton ( whatever spin, limited up to 2 as said in the link above) is a decision for the model, and if the data validate the model .

For example there exists the possible triple vertex W+W-Z which is not allowed in the standard model of particle physics , so if measured will show a need for extending the model. Above the symmetry breaking energies all these particles have zero mass.

One can hypothesize a model where a zero spin graviton has a coupling with these zero mass gauge bosons,which include the photon, and then check if there is any evidence in data and observations. ( a bit hard with the coupling of the gravitational forces being so small). It is the smallness of the gravitational coupling that is the problem.

The main stream physics research models go in the direction of quantizing gravity (a goal not yet reached) in the framework of General relativity, which has to have a spin two graviton, and of course it couples to the gauge bosons, even with zero mass which happens above the symmetry breaking energies, as the massive W and Z are massless there.

Thus a photon and a graviton do have an interaction, as expected , in an appropriate quantized gravitational theory.