Actually, I think the neutrinos might be enough to kill you. Not sure about this, but Wikipedia alleged that in a supernova, the outer parts of the star are blown away by the neutrinos because that’s what gets there first. I don’t quite understand how this can be, but even leaving that aside...
I would presume that if the initial light-blast didn’t actually eat all the way through the planet, then the ashes following behind it only slightly slower, once they got in front of the night side, would be emitting light at intensity sufficient to vaporize the night side too. So, yeah, everyone dies pretty damn fast, I think. Don’t know if the planet’s core stays intact for another minute or whatever.
The matter of the star exerts a downward pressure on the electric-interacting particles. The neutrinos at first are just held in by the random-walk they do from colisions in the very dense part of the star. The trigger for the release is neutrinos leaving the super-dense-random-walk area, allowing it to cool down crazy fast. So when they neutrinos start to emerge they leave the core of the star at near light speed, the same way photons leave the edge of the star. IIRC, they do not need to be accelerated from collapsing to expanding, but the mass does. (took physics an eternity ago, so do not quote me)
Actually, I think the neutrinos might be enough to kill you. Not sure about this, but Wikipedia alleged that in a supernova, the outer parts of the star are blown away by the neutrinos because that’s what gets there first. I don’t quite understand how this can be, but even leaving that aside...
I would presume that if the initial light-blast didn’t actually eat all the way through the planet, then the ashes following behind it only slightly slower, once they got in front of the night side, would be emitting light at intensity sufficient to vaporize the night side too. So, yeah, everyone dies pretty damn fast, I think. Don’t know if the planet’s core stays intact for another minute or whatever.
The matter of the star exerts a downward pressure on the electric-interacting particles. The neutrinos at first are just held in by the random-walk they do from colisions in the very dense part of the star. The trigger for the release is neutrinos leaving the super-dense-random-walk area, allowing it to cool down crazy fast. So when they neutrinos start to emerge they leave the core of the star at near light speed, the same way photons leave the edge of the star. IIRC, they do not need to be accelerated from collapsing to expanding, but the mass does. (took physics an eternity ago, so do not quote me)