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Suekdccia
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- Can the decay of neutrons and protons (assuming it happens, as it is not proven) be avoided in some cases (like certain types of neutron stars, white dwarfs or other systems)?
I was wondering whether the decay of neutrons and protons (if they happen to be able to decay, as it is predicted by some GUTs) could be avoided in some cases.
Let's begin with neutrons:
In principle neutrons have a very short time when they are isolated (around 10 minutes) and they suffer beta decay, but because of electron degeneracy pressure, it is heavily supressed in a neutron star (What stabilizes neutrons against beta decay in a neutron star?).
So, if this happens, then, shouldn't neutron stars be "safe" from the decay of neutrons and protons (in case there is proton decay, as there are almost no protons but mainly neutrons)?
I read an article, A Dying Universe: The Long Term Fate and Evolution of Astrophysical Objects, where they describe that as neutron stars would have protons (for example, they would have ordinary matter in their surface) the protons would decay, decreasing the degeneracy pressure on the neutrons and allowing bets decay to occur. But, I was thinking: Is it impossible for a pure neutron star to exist? So that the the degeneracy pressure would be maintained by electrons (held together by gravity and pressure)?
Then we go for the protons:
Could there be some situations in which, even if protons could decay, this could be somehow avoided? For example, if there was a white dwarf with a high density of electrons, could they maintain the degeneracty pressure and supress proton decay? Or perhaps a very high angular momentum, so that it would cause some kind of force or pressure (like a high centripetal force) that would keep a similar degeneracy pressure that would keep protons from decaying?
If not, can you think of any other ways? Or proton decay, if it occurs, is unavoidable and therefore neutron decay as well?
Let's begin with neutrons:
In principle neutrons have a very short time when they are isolated (around 10 minutes) and they suffer beta decay, but because of electron degeneracy pressure, it is heavily supressed in a neutron star (What stabilizes neutrons against beta decay in a neutron star?).
So, if this happens, then, shouldn't neutron stars be "safe" from the decay of neutrons and protons (in case there is proton decay, as there are almost no protons but mainly neutrons)?
I read an article, A Dying Universe: The Long Term Fate and Evolution of Astrophysical Objects, where they describe that as neutron stars would have protons (for example, they would have ordinary matter in their surface) the protons would decay, decreasing the degeneracy pressure on the neutrons and allowing bets decay to occur. But, I was thinking: Is it impossible for a pure neutron star to exist? So that the the degeneracy pressure would be maintained by electrons (held together by gravity and pressure)?
Then we go for the protons:
Could there be some situations in which, even if protons could decay, this could be somehow avoided? For example, if there was a white dwarf with a high density of electrons, could they maintain the degeneracty pressure and supress proton decay? Or perhaps a very high angular momentum, so that it would cause some kind of force or pressure (like a high centripetal force) that would keep a similar degeneracy pressure that would keep protons from decaying?
If not, can you think of any other ways? Or proton decay, if it occurs, is unavoidable and therefore neutron decay as well?