Okay, I'm gonna make this simple, because this concept needs it:
1. 2 photons entangle
2. 1 of them enters a black hole and freezes in time
3. Time in the black hole has been still for eons. If one quantum entangled particle enters it can and will be in a phase of changing entanglement in a still time. Thus all other particles in the black hole are together in that phase.
4. When the outer photon entangles with something else the previous entanglement is droped, making the photon loose all its quantum entanglement entropy.
5. When 4 happens all the entangled entropy in the black hole is released. But where is it released?
6 Half at one and half at the other?
I do not think you release entanglement. The rest I have no idea about.
]]>That quantum entanglement is related to the Einstein Paradox which he called spooky action at distance. His thought experiment proved to him that if quantum mechanics was true then the laws of conservation of charge and spin were not.
Bell supposedly patched it up but it was rekindled in an exchange between Gunter Nimtz and Raymond Chow over the phenomena of quantum tunneling. Nimtz says he can transmit information at 300 times the speed of light, Chow says nope.
]]>Nowhere does that article say a photon decays or can be broken down into anything else.
]]>Look under concept, clearly a photon can decay into for instance heat?
"When particles decay into other particles, these decays must obey the various conservation laws. As a result, pairs of particles can be generated that are required to be in certain quantum states."
I thought that decay must apply in some mean to photons too?
]]>Nope, because a photon is if I remember one of four fundamental particles. It cannot be split into anything smaller.
]]>If 2 photons became entangled and split up, one entering the black hole, what if the whole black hole becomes entangled?
Wouldn't then a heck of an amount of entanglement entropy be released when the other photon re-entangles?
Quantum Entanglement leaves me sort of tied up. I do not know if that is what is happening. The Hawking paper that I was talking about says that it will take
1 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 000 years for an average black hole to dissove.
]]>So basically, when the outside quantumentangled particle had the entanglement with the particle inside the black hole, the particle inside couldn't possibly have lost its entanglement unless the outside entangled particle entangles with some other particle, in which case the quantumentanglement inside the black hole must've been dissolved and the energy left the black hole faster then the speed of light?
And since time doesn't pass in the black hole, allmost all matter inside are entangled together timewise, and hence all quantumentanglements in the black hole leaves it when one entangled particle outside, entangles with something else instead.
]]>I have heard virtual particle production, according to Hawking because of it a black will slowly dissolve given enough time.
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