Quote:
Originally Posted by Erasmus00
Well, there can't be coulomb attraction between protons (the coulomb force is repelling them!). That leaves only a magnetic force, but the observed magnetic moment of protons (around a bohr magneton) leads to forces much smaller than the coulomb repulsion by the observed charge.
-Will
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If you understood my article, you would have known that I said a coulomb attractive force is present in the deuteron by the presence of an electron between the two protons with similar magnetic spins to complete the SF binding.
I said these protons have 'very' high spin rates in these central regions of the stars to create 'very' powerful magnetic binding to enhance the electrons attraction between the two protons, IMHO.
Naturally, the electron and one proton comprise the neutron in the deuteron.
It is a known fact that the neutron decays into a proton and electron when isolated from the other proton.
This happens because the high spin separates the two that have opposing magnetic fields that cause the separation plus the fact that in this case, the electron also acqures orbital momentum because of this separation, IMHO.
The 'nuclear magneton' you mention above is in a hydrogen atom and has no comparison to the protons in the central regions of the stars.
NS
