Yes, it's often described that way, but not the case. Quoting from "Quantum Fields in Curved Space" by Birrell and Davies,That radiation is described as being emitted by the event horizon
bcrowell said:As a simple example, suppose an observer in flat spacetime is accelerating continuously in a rocket. There is a region of spacetime from which information can never propagate to this observer, and the edge of this region is seen by this observer as a horizon.
We don't really know for sure how quantum mechanics interfaces to gravity, but one principle that seems to hold true is that observers see Hawking radiation coming from any horizon. It doesn't have to be a black hole's horizon.
And so are particles. The important realization that lies behind Hawking radiation is that the presence or absence of particles is not absolute. One observer may detect particles while another observer detects none. In particular a uniformly accelerating observer in Minkowski space detects a thermal bath of particles associated with his Rindler horizon.That really puzzles me, because such a horizon is just an observational effect
Bill_K said:And so are particles. The important realization that lies behind Hawking radiation is that the presence or absence of particles is not absolute. One observer may detect particles while another observer detects none. In particular a uniformly accelerating observer in Minkowski space detects a thermal bath of particles associated with his Rindler horizon.
phinds said:OK, but this makes it sound like you are saying that Hawking radiation is just an optical illusion, but if it is REAL, as I thought it to be, it has the physical effect of reducing the mass of the BH. How is that consistent with "one observer may detect particles while another observer detects none" ? It either does or does not reduce the mass of the BH. I'm sure you're not saying it is observer dependant, so are you saying it does not?
I think the answer to this is no, and one way to see that it has to be no is that it would violate the equivalence principle. One way of stating the e.p. is that spacetime is always locally Minkowski. Spacetime doesn't locally have special properties.phinds said:But is is not true that the EH of a black hole, while not actually a physical construct, has nonetheless a local physical effect that allows split virtual particles to be separated, and thus become Hawking radiation?
I haven't dug deeply into the theory of Hawking radiation, but my understanding is that this picture of splitting pairs of virtual particles is really a popularization and not to be taken completely seriously. Here's a discussion of that by Baez: http://math.ucr.edu/home/baez/physics/Relativity/BlackHoles/hawking.htmlphinds said:That really puzzles me, because such a horizon is just an observational effect that has no localized physical ability to do anything the way a BH's EH does so why would not split virtual particles just recombine and NOT become Hawking radiation?
bcrowell said:I haven't dug deeply into the theory of Hawking radiation, but my understanding is that this picture of splitting pairs of virtual particles is really a popularization and not to be taken completely seriously.
bcrowell said:An observer who has already fallen through the horizon of a black hole does not perceive the region outside the black hole as lying behind a horizon. Information from outside the horizon can still propagate to him (until he goes splat at the singularity). So I don't think any Hawking radiation is observable by him.
bcrowell said:I think the answer to this is no, and one way to see that it has to be no is that it would violate the equivalence principle. One way of stating the e.p. is that spacetime is always locally Minkowski. Spacetime doesn't locally have special properties.
Hawking radiation is a theoretical phenomenon proposed by physicist Stephen Hawking in which black holes emit radiation due to quantum effects near the event horizon.
Hawking radiation is thought to be created when pairs of particles are spontaneously generated near the event horizon of a black hole. One particle is pulled into the black hole while the other escapes, resulting in a net loss of mass for the black hole.
Yes, Hawking radiation is thought to cause black holes to gradually lose mass and eventually evaporate. However, this process is extremely slow and would take an incredibly long time for a black hole to completely evaporate.
Hawking radiation is different from other types of radiation because it is created by quantum effects at the event horizon of a black hole, rather than by nuclear reactions or other processes. It is also unique in that it is thought to be emitted by black holes, which are typically considered to be objects that do not emit radiation.
Hawking radiation has not yet been observed directly, but there is strong theoretical and mathematical evidence supporting its existence. It is difficult to observe due to its small amount and the fact that it would be emitted by black holes that are typically located far away in space. However, scientists continue to search for ways to detect and measure Hawking radiation.