The discussion centers on the differences between black holes and the Big Bang, emphasizing that the standard model of a black hole does not apply to the Big Bang due to distinct space-time geometries. Participants assert that the Big Bang likely originated from a quantum fluctuation, with energy/momentum driving the expansion of space, counteracting gravitational forces. The conversation also touches on the implications of energy conservation in General Relativity (GR) and the potential for measuring the effects of cosmic expansion in laboratory settings.
PREREQUISITESAstronomers, physicists, cosmologists, and anyone interested in the fundamental principles of the universe's origin and the interplay between gravity and quantum mechanics.
zhermes said:Good question. No it would not be the same for the big bang, because the standard picture of a 'black hole' applies to a particular space-time geometry (e.g. a point mass in an otherwise flat geometry), which is very different from the models of Big Bang / inflation.
GR does apply to both cases, but you get different results. Space-time itself can carry energy/momentum; in the big bang, this energy/momentum helps drive material outward in an expansion of space. That's not present in a standard black-hole.Dinosky said:Thank you for the reply. I have difficulties in seeing the difference between the two, as if GR is the governing equation that applies to both cases, it should give the same implication for the starting point of BB where gravity should be large enough to stop any possible expansion? Really not sure.
That is good logic, but it misses some of the details of inflation and the big bang---you can think of it in terms of there just being a really strong expanding energy/momentum during the BB which was great enough to resist the gravitational pull of so much matter.Dinosky said:BTW, if the density of the present universe is large enough, it should be able to halt the expansion and ultimately lead to big crunch. That's why I think in the early stage of BB, the density is so high and gravity should be large enough (don't know any calculation) to stop it.
Unfortunately, that's part of why the balloon surface is only an analogy. In GR space-time and matter are coupled together, and are coupled in a highly non-linear (and thus complex) manner. Let's try a different analogy:Dinosky said:It is also puzzling that the mass-density inside space-time governs its evolution and curvature given that mass inside space time has no degree of freedom outside space time dimension. Using the balloon surface analogy, if matters are restricted to move along the surface, how can it affect the balloon's expansion?
That's the point of the post, the OP is asking why it bears so little resemblance to a BB, when surely a (naive) calculation of the escape velocity for the (obscenely) high primordial energy density would be greater than the speed of light.Chronos said:The most plausible explanation at present, IMO, is the BB arose from a quantum fluctuation. It bears little resemblance to a black hole...
zhermes said:GR does apply to both cases, but you get different results. Space-time itself can carry energy/momentum; in the big bang, this energy/momentum helps drive material outward in an expansion of space. That's not present in a standard black-hole.
That is good logic, but it misses some of the details of inflation and the big bang---you can think of it in terms of there just being a really strong expanding energy/momentum during the BB which was great enough to resist the gravitational pull of so much matter.
Unfortunately, that's part of why the balloon surface is only an analogy. In GR space-time and matter are coupled together, and are coupled in a highly non-linear (and thus complex) manner. Let's try a different analogy:
Lets say you throw some object (maybe a stone, maybe a model boat, whatever) across the surface of a pond. That object will cause ripples in the surface of the water. Those ripples and waves themselves could cause the object to move---and then the new motion of object could cause further waves, motions, turbulence etc in the water.
In the case of GR the interactions are far more complex and long-ranged.
Most theories manage to maintain conservation of energy... I'm sorry I don't know enough about the details to say anything else.Dinosky said:Thank you for the insights. Does it mean that in BB model there is non-conservation of energy? In other words in expanding universe the total energy content of the whole universe is increasing, isn't it?
You're absolutely right, that should theoretically be the case. Unfortunately that force would be so ridiculously small that I can guarantee there is no chance that experiment would be doable anytime soon.Dinosky said:I have an idea that the expansion of universe should in principle be measurable in laboratory. ... we should be able to observe that a force is necessary to keep any two objects at the same distance apart inside a laboratory.
zhermes said:Most theories manage to maintain conservation of energy... I'm sorry I don't know enough about the details to say anything else.
You're absolutely right, that should theoretically be the case. Unfortunately that force would be so ridiculously small that I can guarantee there is no chance that experiment would be doable anytime soon.