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arivero
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Last december I was asking for the possibility to couple the highest massive bosons to the nucleus. I was aiming for some kind of many body effect to give relevance to the total mass of the nucleus, besides the one of the independent nucleon.
To get this, one expects the contribution of more massive particles to be only a perturbation of the strong coupling induced by pions (and the other lesser massive particles). So I concentrated in the upper side of the spectrum of particles: top mesons, higgs, and W-Z, even if some people told me about researching the rest of particles.
Well, I am surprised because I finally did a plot of the medium range bosons (J/Psi, B, and Upsilon), see it at
http://dftuz.unizar.es/~rivero/research/nucleo/mesones.pdf
and, hmm, it does not contradict the possibility of relating them to total mass. There are two main gaps in the spectrum: one between the J/Psi particles and the bottom mesons B(s)-B(c), another between the bottom mesons and the Upsilon. The gaps happen to be at 5 atomic mass units and 7-8 amu. And no nucleus happens at 5 or 7aAmu, these are the only known atomic numbers where there is not stable nucleus. So the low energy nucleus also could be said to notice the masses of medium mass mesons.
[edited] Honestly, the role of these mesons is unclear. The nuclei 4He, 8B (that disintegrates to two 4He) and 12C hold the highest energies per nucleon in the zone. The mesons could be helping to this, or on the contrary contributing to decrease the energy per nucleon of the extant nuclei. The increased stability of even-even nucleus goes further, until a total of 30 nucleons, where the odd-odd nucleui begin to be stronger.
Yours,
Alejandro
PS: the units of the plot are MeV. Horizontal axis is mass, vertical axis is decay width. In the mass scale, the grid shows multiples of atomic mass. At 0,350 I have plotted nuclei mass for reference.
[EDITED 24 Feb]: the most recent version of the manuscript is not the one at arxiv, but the one in my site,
http://dftuz.unizar.es/~rivero/research/masas.pdf
To get this, one expects the contribution of more massive particles to be only a perturbation of the strong coupling induced by pions (and the other lesser massive particles). So I concentrated in the upper side of the spectrum of particles: top mesons, higgs, and W-Z, even if some people told me about researching the rest of particles.
Well, I am surprised because I finally did a plot of the medium range bosons (J/Psi, B, and Upsilon), see it at
http://dftuz.unizar.es/~rivero/research/nucleo/mesones.pdf
and, hmm, it does not contradict the possibility of relating them to total mass. There are two main gaps in the spectrum: one between the J/Psi particles and the bottom mesons B(s)-B(c), another between the bottom mesons and the Upsilon. The gaps happen to be at 5 atomic mass units and 7-8 amu. And no nucleus happens at 5 or 7aAmu, these are the only known atomic numbers where there is not stable nucleus. So the low energy nucleus also could be said to notice the masses of medium mass mesons.
[edited] Honestly, the role of these mesons is unclear. The nuclei 4He, 8B (that disintegrates to two 4He) and 12C hold the highest energies per nucleon in the zone. The mesons could be helping to this, or on the contrary contributing to decrease the energy per nucleon of the extant nuclei. The increased stability of even-even nucleus goes further, until a total of 30 nucleons, where the odd-odd nucleui begin to be stronger.
Yours,
Alejandro
PS: the units of the plot are MeV. Horizontal axis is mass, vertical axis is decay width. In the mass scale, the grid shows multiples of atomic mass. At 0,350 I have plotted nuclei mass for reference.
[EDITED 24 Feb]: the most recent version of the manuscript is not the one at arxiv, but the one in my site,
http://dftuz.unizar.es/~rivero/research/masas.pdf
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