As I understand it, gravitational interactions between the different stars in the galaxy continually push the kinetic energy distribution of the stars towards thermal equilibrium. But in thermal equilibrium, there is always a high-energy tail that has a velocity above the escape velocity for the galaxy.Tanelorn said:From post 25:
Ben, one other point in that link you provided. I am havng a hard time visualising how most of the stars will eventually be ejected from old eliptical galaxies.
I am still unable to figure out why this happens. Can anyone offer a reason?
Well, two points here. First, it is only a minuscule fraction that are ejected at any given time. The rate of ejection due to this effect is vastly, vastly slower than the rate of formation, so it just isn't an impediment. Secondly, a major factor in forming galaxies is the friction of the gas that is later formed into stars. This friction tends to cause the gas to collapse inward quite rapidly as it loses energy. Once the stars form and the friction basically goes away, this collapse is halted. It is only then that some tiny fraction of the stars start getting ejected from the galaxy.Tanelorn said:If there are forces that eject nearly all the stars out of an eliptical galaxy you kind of wonder how they ever got gravitationally bound in the first place! :)
I don't know what you're asking. To me, those are different words for the exact same thing.Chronos said:What suggests decaying orbits result in gravitational collapse of an orbital system?
Why would it cease to be valid? The second law of thermodynamics states that entropy never decreases. When the universe reaches equilibrium, entropy will be constant, so not decreasing.Cosmo Novice said:Assuming final entropic disorder and a heat death, does this mean at the exact "time" of final heat death (all matter/energy existing independently in the smallest quantities possible within its own cosmological event horizon) that the second law of thermodynamics ceases to be a valid law?
Cosmo Novice said:Assuming final entropic disorder and a heat death, does this mean at the exact "time" of final heat death (all matter/energy existing independently in the smallest quantities possible within its own cosmological event horizon) that the second law of thermodynamics ceases to be a valid law?
I am not promoting this as true in anyway but I always percieve final heat death to be t=0 and think that we should be counting backwards to 0 instead of forwards :) Maybe my brain ticks the wrong way.
I don't think so. The fact that our universe started is, to me, proof positive that another universe can start again.Tanelorn said:Again a very sad conclusion and end to the universe really. No hope of a repeat cycle, just a long slow fade away, like the fading heat of a bonfire from the night before. Darn.. makes you wonder what is the point sometimes..
I should mention, however, that the problem that Baez pointed out is a very real problem. It is very clear that there is a significant issue with respect to how a new universe can begin. These days, I'm leaning towards the de Sitter Equilibrium idea. Here is a paper describing how inflation is likely in this picture:Tanelorn said:Chalnoth, I think you are just trying to make me feel better, well... you succeeded! Thanks Chris
Well, not quite. That view runs into the precise problems that Baez mentioned in that essay you linked. However, it is conceivable that new regions of space-time are periodically born that spawn new universes. Ours, however, is most likely to undergo heat death and remain that way forever, even if it does spawn new universes.Tanelorn said:Perhaps we can view the gradual winding down of the universe as rather like a great cuckoo clock. When it stops it just needs someone or something to come along and wind it back up again.
That seems to me a pretty tall order.Tanelorn said:All that would be required would be for dark energy to slow down and switch sign. Perhaps this way it could yet be the driving force for a cyclical universe?
Tanelorn said:Perhaps we can view the gradual winding down of the universe as rather like a great cuckoo clock. When it stops it just needs someone or something to come along and wind it back up again.
All that would be required would be for dark energy to slow down and switch sign. Perhaps this way it could yet be the driving force for a cyclical universe?
There isn't any reason to believe this is the case. If dark energy really is a cosmological constant, its value was simply irrelevant until a few billion years ago, but there's no reason to believe it changed.Tanelorn said:I understood that dark energy has already changed once during the history of the universe. I believe I read that it started increasing about 7B years ago, unless I misunderstood something?
So I was just asking if there is any reason why, in the very distant future, dark energy could not start changing again?
Seems unlikely. I mean, if you want to wait for some obscene number of years, it will happen. But counting on simple recurrence doesn't solve the entropy problems. You need to have an alternative pathway to producing new regions of space-time to make the entropy make sense.Tanelorn said:It seems more elegant for all matter energy space and time to return to inital conditions, perhaps like conservation of energy or an electron positron pair being spontaneously created and destroyed. There is no possibility of an opposite process to inflation to achieve something like this?
ryan_m_b said:This essentially means eventually the energy will be spread out evenly, it is currently thought that this will lead to http://en.wikipedia.org/wiki/Heat_death_of_the_universe" in about 10100 years.
Well, it's not a theory. It's a conclusion based upon our knowledge of the theories of physics. It isn't absolutely necessary to test each end every conceivable conclusion of a theory to be confident in its veracity.MathematicalPhysicist said:A long time to falsify a theory.
:tongue:
Chalnoth said:Well, it's not a theory. It's a conclusion based upon our knowledge of the theories of physics. It isn't absolutely necessary to test each end every conceivable conclusion of a theory to be confident in its veracity.
While this is true, the ways in which theory would have to change to change the conclusion of heat death are rather unlikely. Basically, in order to avoid heat death you would need:MathematicalPhysicist said:Indeed, upon our current theories, as every empirical science things may change in the years to come in our perception of nature.
I'd like to know what line of reasoning he was using here. But, suffice it to say, this sort of thing depends quite strongly upon high-energy physics far beyond what we have been able to test in the lab so far, so it is somewhat foolish to draw conclusions there. The heat death of the universe, however, does not depend upon anything that isn't well-tested in the lab, except for the nature of dark energy and the spatial curvature.MathematicalPhysicist said:In a class I took as an undergrad, our teacher of QM 2, in the last lecture showed us a calculation that even according to QM (before QFT) the universe shouldn't have gone so far, in fact it should have collapsed in a matter of a few seconds.