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Quote from: Bored chemist on 08/08/2020 14:48:41Then it wouldn't be a proton any more.It would still be a proton because the proton has got other properties that do not go into the Higgs. The Higgs is made of some of the proton parts.
Then it wouldn't be a proton any more.
A proton cannot contain parts of a Higgs in one frame and not in another.
Not to mention that the Higgs is a fundamental particle. It isn't, to the best of our knowledge, made of anything simpler than itself.
And what about decay of the muon
Yes, that makes perfect sense because 0.9 is much bigger than 125.
Then the Z boson was actually detected in 1983. That's strong evidence that the weak nuclear force exists.
Don't be sarcastic. The proton's relativistic mass is > 125 GeV/c2.
I can conceive of what ordinary physics cannot.
Space is at rest relative to the proton. Relativistic mass makes more real little circles (see figure above) as far as space is concerned. The rest frame of the proton is irrelevant for space.
In my model the Higgs is made of a Riemann sphere with left out events of spacetime - I can conceive of what ordinary physics cannot.
The muon also decays by the strong force
They detected a photon with mass.
Sounds like you are contradicting relativity.
It doesn't even interact with the strong nuclear force, so that doesn't work.
mu-minus binds with a muon antineutrino
The mu-minus binds with a muon antineutrino to form a pi-minus that does feel the strong force.
Gravity won't work because it's far too weak on that scale.
They can bind by Gravity if the antineutrino is very precisely headed for the muon. Gravity becomes large for small distances. Since the antineutrino is light only a very tiny force is required to accelerate it to the muon.
The muon and antineutrino acquire color charge just before they bind by the strong force into a pion.