Vanadium 50 said:For BH's smaller than ~70 microns, Hawking radiation dominates and the BH will get smaller. For BH's larger than this, absorbing radiation dominates and the BH will get bigger.
Yes. For now. EVENTUALLY, Hawking radiation takes over and they get smaller and smaller. I've seen numbers like 10E80 years for total evaporation of big ones.cosmik debris said:Does this mean that the big black holes out there don't decay and go pop but just get bigger?
Cheers
phinds said:I've seen numbers like 10E80 years for total evaporation of big ones.
Earth-bound. Not that the Earth will be around for anything more than a totally trivial portion of that time. Better to call it a co-moving observer (and if you don't know exactly what that means, look it up)Grinkle said:I am curious - by an Earth bound clock, or by the clock of an observer free-falling into the hole, or some different clock?
phinds said:Yes. For now. EVENTUALLY, Hawking radiation takes over and they get smaller and smaller
10E80 years is a LONG time, so yes.Vanadium 50 said:Is that true in general? Remember, Hawking radiation doesn't win until the BH is hotter than the CMBR, and while it is absorbing all that CMB radiation it is cooling.
phinds said:10E80 years is a LONG time, so yes.
I don't have the calculation but I've seen that stat here several times. Eventually the CMB fades away, effectively, as does ALL radiation coming at a BH and Hawking Radiation takes over. Again, 10E80 is just a STAGGERINGLY long time.Vanadium 50 said:Yes, and it's absorbing radiation all this time, growing and cooling. Have you calculated that for a BH of any size it eventually evaporates? I suppose one could add for any time and any cosmology.
In short - can you show me a calculation or quantitative argument?
Vanadium 50 said:gneil, you're right that the universe has a long time to cool. But by the same argument, the BH has a long time to accrete.
I'm not arguing 10^80 years is a short time. I am asking is there a mass so large that the CMBR accretion always exceeds Hawking radiation. Yes, both decrease with time, and yes, 10^80 years is a long time. My question is whether there exists a mass (and possibly a cosmology) where the two curves never cross. I am willing to believe there is, and I am willing to believe there isn't. But if possible, I'd like a more quantitative answer than "10^80 is big" or "I read somewhere".
Hawking radiation is a type of thermal radiation that is predicted to be emitted by black holes due to quantum effects near their event horizon. It differs from cosmic background radiation, which is a remnant of the Big Bang and exists throughout the entire universe.
Hawking radiation was first predicted by physicist Stephen Hawking in 1974 through his research on black holes and quantum mechanics. It has not yet been directly observed, but its effects have been observed in experiments and simulations.
No, Hawking radiation is distinct from the cosmic background radiation. The cosmic background radiation is a low-energy form of radiation that is spread evenly throughout the universe, while Hawking radiation is a high-energy form of radiation that is emitted only from black holes.
Hawking radiation is an important factor in our understanding of black holes, as it provides a mechanism for them to eventually evaporate and disappear. This challenges the traditional notion that black holes are completely black and have an infinite lifespan.
While Hawking radiation has not yet been directly observed, it has implications for the study of black holes and the understanding of the universe at a fundamental level. It also has potential applications in fields such as quantum mechanics and cosmology.