The discussion revolves around the implications of a recent paper that challenges the necessity of dark energy (Λ) in cosmology, particularly in the context of N-body simulations that account for general relativity (GR). Participants explore whether the apparent accelerated expansion of the universe can be explained through local inhomogeneities and the formation of cosmic structures, rather than invoking dark energy.
Participants express differing interpretations of the implications of the paper, with no consensus on whether the arguments presented effectively challenge the necessity of dark energy. The discussion remains unresolved regarding the validity of the claims and the interpretations of the simulations.
Participants note limitations in understanding the implications of the discussed papers, including the complexity of non-linear effects and the need for further analysis to clarify the role of inhomogeneities in cosmic expansion.
This does not seem to be the case to me. The difference between their simulations and the ΛCDM model is that their simulations treat a universe that is not homogeneous, i.e., it does away with the assumptions that go into the FLRW universe and therefore the ΛCDM model. This does not have to do with Newtonian approximations, but is an assumption that the universe can be treated as essentially homogenous on large scales.phyzguy said:I think they are saying that past simulations have used Newtonian approximations that don't properly account for density fluctuations.
Orodruin said:This does not seem to be the case to me. The difference between their simulations and the ΛCDM model is that their simulations treat a universe that is not homogeneous, i.e., it does away with the assumptions that go into the FLRW universe and therefore the ΛCDM model. This does not have to do with Newtonian approximations, but is an assumption that the universe can be treated as essentially homogenous on large scales.
Chalnoth said:It sounds like what they're saying is that the formation of structure itself produces the appearance of an accelerated expansion, which is not caught in typical perturbative theory due to the nonlinear nature of the process.
I remember a lot of theorists looking into ideas like this back in the early-mid 2000's (Rocky Kolb was a major proponent at the time), and my understanding was that the idea had been largely debunked. I'm not sure if this paper throws a wrench into that previous conclusion.
My recollection is that the "no-go" theorem was just the first round of argument against the idea, that further analysis showed that you can't really reproduce the observed expansion without dark energy with the growth of structure alone, but also have to have large-scale inhomogeneity as well. But to be fair, it's been a while.phyzguy said:Thanks for pointing this out. Here's a paper by Kolb, et.al. that supports the basic idea, and another paper that disputes the "no-go" theorem, which I assume is what you mean by the debunking. It will be interesting to see where this leads.
windy miller said:Ive seen a few papers recently ( I think one even made into Nature) casting doubt in the existence of accelerated expansion. what I would like to know from anyone who thinks this is plausible is how to do you explain then the measured flatness of the cosmos? As I understood without lambda there isn't enough stuff in the universe to make it flat.
It can be hard to tell from just looking at a couple of papers. Communicating with a cosmologist actively working in the general area would probably give you a pretty clear picture of the overall status. Sadly, it's been too many years for me.phyzguy said:Yet another paper on this topic posted on the arXiv today. Clearly the issue is far from settled. I found this one very interesting, as the authors studied the impact of inhomogeneities on an exact solution to the Einstein equations, and found that the effects can be significant. However, they don't claim to have answered whether the large-scale accelerated expansion can be explained by the non-linear effects of the growth of structure.
HI phyzguy:phyzguy said:These regions expand faster because of their lower density, and so the apparent expansion of the universe accelerates.
Buzz Bloom said:HI phyzguy: However, I have difficulty visualizing this state evolving as a result of further expansion with respect to co-moving coordinates with the lower density areas expanding faster than the higher density areas. The best I can do is with the balloon analogy that marcus wrote about so well. The whole balloon expands uniformly
The point is that you don't know this. Again quoting from the Racz, et.al. paper, they say,Also, the overall rate of balloon expansion depends on the average density, and not on the lower density of the larger volume areas.
The point is that it is not clear what GR predicts. The Friedmann equation assumes the density is spatially uniform, and today's universe is nowhere near uniform in density. Nobody has solved the Einstein Field Equations for the non-uniform density present in the universe today. The paper I linked in Post #10 is an attempt to do this in a small region, and they conclude that the impact of the density fluctuations cannot be ignored."it is not the average but the typical energy density that governs the expansion rate of the Universe" seems to be distinctly different the behavior GR predicts.
Hi phzguy:phyzguy said:The paper I linked in Post #10 is an attempt to do this in a small region, and they conclude that the impact of the density fluctuations cannot be ignored.
Hi phzguy:phyzguy said:Why must the balloon expand uniformly?
Interesting question. Ignoring the masses of the black holes would mean that according to the Friedmann equations this universe should expand exponentially.This however is what cosmologists expect for the far future when the average matter density is ignorable.Buzz Bloom said:I am unable to do the math, but I have been thinking about a hypothetical universe which is mostly a vacuum, but there is included a distribution of black holes throughout this universe such that the average mass density equals the estimated total mass density of our current universe. Do you think the paper supports an argument that in this hypothetical universe the mass of all the black holes can be ignored when calculating the rate of expansion?
I have read these papers, but frankly I do not understand enough of their model (back-reaction) to be able to see the mechanism that would a cause global appearance of accelerated expansion. I can understand that there may be a region (say on the far side of a void) from us that may have a kinematic recession rate that is larger than the Hubble flow, but how that makes the overall Hubble flow faster, I do not follow.phyzguy said:The point is that it is not clear what GR predicts. The Friedmann equation assumes the density is spatially uniform, and today's universe is nowhere near uniform in density. Nobody has solved the Einstein Field Equations for the non-uniform density present in the universe today. The paper I linked in Post #10 is an attempt to do this in a small region, and they conclude that the impact of the density fluctuations cannot be ignored.
Jorrie said:I have read these papers, but frankly I do not understand enough of their model (back-reaction) to be able to see the mechanism that would a cause global appearance of accelerated expansion. I can understand that there may be a region (say on the far side of a void) from us that may have a kinematic recession rate that is larger than the Hubble flow, but how that makes the overall Hubble flow faster, I do not follow.
I really don't see how this can work. It's certainly very much contrary to the way gravity works in most every other situation. With a spherically-symmetric mass distribution, for example, the gravitational attraction at some specific distance depends only upon the mass contained within a sphere of the radius of that distance. Whether that mass is distributed evenly or concentrated in the center, or in a shell, makes precisely zero difference as to the behavior of the test particle.phyzguy said:Well, my understanding is that what they are saying is that the low density regions expand faster because they contain less mass. Because most of the volume is lower than average density, this causes the global expansion to be faster than if the density were uniform. I guess another way of saying it is that most of the volume in the universe is "on the far side of a void" (or at least a lower density region) from us.
This is not very convincing, to me at least - if I consider a void to be comoving on average, it seems to be just standard perturbations that cause a peculiar flow away from the center, i.e. it is a conventional 'repeller'. This would mean that the recession rates between opposite sides of a void would exceed the average Hubble flow. But the overdense regions would have the opposite effect, i.e. they are attractors. And over large enough volumes, I think that they have to average out.phyzguy said:Well, my understanding is that what they are saying is that the low density regions expand faster because they contain less mass. Because most of the volume is lower than average density, this causes the global expansion to be faster than if the density were uniform. I guess another way of saying it is that most of the volume in the universe is "on the far side of a void" (or at least a lower density region) from us.
Jorrie said:This is not very convincing, to me at least - if I consider a void to be comoving on average, it seems to be just standard perturbations that cause a peculiar flow away from the center, i.e. it is a conventional 'repeller'. This would mean that the recession rates between opposite sides of a void would exceed the average Hubble flow. But the overdense regions would have the opposite effect, i.e. they are attractors. And over large enough volumes, I think that they have to average out.
I don't see why the underdense regions should cause the overdense regions to recede from one another more rapidly.phyzguy said:The authors of the study I linked in post #1 (see their figure 5) claim that at late times, like today, the universe is dominated by underdense regions - i.e. much more volume is underdense than overdense. This is why it does not average out.
I can see peculiar movements of matter in the underdense regions towards the surrounding overdense structures. I can also see the 'walls' of the overdense regions to move towards the local center of mass. In this sense voids grow and structures shrink during structure formation. But take a large enough sample, including voids and overdensities, and you still have the same amount of mass and kinetic energy in there. Without the negative pressure of dark energy, I fail to see how the overall expansion rate can accelerate. Yet this is what there Fig. 2 seems to suggest.Chalnoth said:I don't see why the underdense regions should cause the overdense regions to recede from one another more rapidly.
Buzz Bloom said:Hi physguy:
I have been trying to do an Internet search to find out more about Szekeres models. I found a lot of papers, but none of the ones whose abstracts I looked at actually mentioned having a definition of what a Szekeres model is. I would appreciate any links you can make to an article which defines this.
Regards,
Buzz