Does a finite universe make sense to you?

In summary, the universe is often described as infinite and expanding in all directions, with no edge or boundary. This is due to the theory that the universe is shaped like a sphere, where traveling in a straight path would eventually bring you back to your starting point. This concept is difficult to grasp, but is supported by the fact that the universe is constantly expanding and has no observable end. There are also theories that suggest our universe originated from another, larger universe and that there may be many universes within a "cosmic landscape." However, these theories are not widely accepted and are still being explored by a minority of cosmologists and theoretical physicists.
  • #141
Response to #140

Hi Kev, I started to take a look at the gravitational implications of black holes and noticed the poll raised by Marcus in this forum. Therefore, I decided to raise a few basic questions on cosmology although, at the moment, I am simply trying to get a better handle on what is substantiated theory and what is still speculative.

I think Jennifer was making a distinction between spacetime and space, where space expands while spacetime does not. I am not clear on how that distinction is defined but Jennifer is usually pretty well informed on this stuff.

On the basis of a space-time diagram, I would of thought that any change to the space axis would explicitly change the resultant hypotenuses of spacetime, but maybe I missing the subtlety of the point being raised.

In my understanding they (curved spacetime and the open/closed issue) are synonymous in the context of cosmology but hopefully someone will clear that up.

I guess I was trying to highlight some different perspectives. 1) On a local level, spacetime can be almost infinitely curved, e.g. black hole, but has no practical bearing on the overall open/closed issue. 2) the open/closed issue seems to depend on the total energy-mass density of the universe, (the issue of pressure touched on below) and, as a generalisation, measurements suggest that [k -> 0], which in-turn suggests that the universe is essentially flat. However, picking up on your point:

It is worth noting that an exactly flat universe only requires the universe to be infinite if the cosmological constant is zero.

As I understand the situation, which may be wrong, the cosmological constant is still a viable part of cosmology because only 30% of energy-mass density required to make the universe flat can be accounted for. In essence, the cosmological constant takes up the slack and is said to tie-up with the idea of quantum mechanical vacuum energy, which in-turn may provide an answer for why the rate of expansion appears to be accelerating and not decelerating, i.e. the cosmological constant behaves gravitationally like matter and energy except that it has negative pressure. However, I am slightly confused on the exact breakdown of the accepted energy-mass density because I have often seen a 4% matter, 21% cold dark matter, 75% dark energy split accompanied by the 30% statement above. My confusion with this statement is 1) was not sure there was any verified acceptance of dark matter or energy? 2) what is the make-up of the 30% that has been accounted?

---------------
As a slight aside, many texts explain the expansion and age of the universe via reference to the Friedmann equation set. This leads to different rate of expansion due to the dominance of matter and radiation in the universe. However, it appears that the actual timeline now being associated with standard model are derived on a different, or refined, set of assumptions, which I have not yet got a clear picture. Hence the similar nature of the discussion in the following thread: https://www.physicsforums.com/showthread.php?t=243968
---------------

The current observational data is just on the closed side of being exactly flat but possibly too close to call at the moment. The apparent lack of gravity despite the obvious fact that there are bodies with mass in the universe is explained by the anti-gravitational effect of the cosmological constant otherwise known as dark energy.

One problem with the cosmological constant is the enormous coincidence that the anti gravity effect exactly balances the gravity effect to give an apparent flat universe at only one epoch in the history of the universe and that happens to be now. Statistically the coincidence is of the order of billions to one against.

Two good points duly noted. There is a paper referenced in the poll concerning the universe as a black hole that seems to question the validity of the cosmological constant, but I suspect there might be another dozen that support it:
http://arxiv.org/abs/0711.4810

The significance of the exterior shells is easily seen when you consider a clock in a hollow cavity at the centre of the Earth. It will be running slower that a clock on the surface of the Earth despite the fact that the Newtonian shell theorem suggests there is no gravitational acceleration or force inside a hollow shell. The gravitational time dilation is a function of gravitational potential and not of gravitational acceleration. Gravitational potential is not independent of mass in external concentric shells.

Another good point that I need to consider. Does the statement imply that a clock in a hollow cavity surrounded by a uniform shell would feel no gravitational acceleration, but would still be subject to time dilation?

At this point I should really apologises to the originator of this thread because I recognise that I have wandered off the topic originally posted, although I believe that it does have some relevance to the question raised. However, I would still like to better understand what evidence supports the 2D balloon analogy that leads to the suggestion of a 4D universe that wraps around and, in doing so, avoids any ‘gravitational gradient difference’ on the scale of the universe, especially if current observations imply an essentially a flat universe.
 
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  • #142
mysearch said:
...
As I understand the situation, which may be wrong, the cosmological constant is still a viable part of cosmology because only 30% of energy-mass density required to make the universe flat can be accounted for. In essence, the cosmological constant takes up the slack and is said to tie-up with the idea of quantum mechanical vacuum energy, which in-turn may provide an answer for why the rate of expansion appears to be accelerating and not decelerating, i.e. the cosmological constant behaves gravitationally like matter and energy except that it has negative pressure. However, I am slightly confused on the exact breakdown of the accepted energy-mass density because I have often seen a 4% matter, 21% cold dark matter, 75% dark energy split accompanied by the 30% statement above. My confusion with this statement is 1) was not sure there was any verified acceptance of dark matter or energy? 2) what is the make-up of the 30% that has been accounted?

On the face of it the "accounted for" energy mass density should be 25% made up of 4% visible matter seen in stars and 21% cold dark matter estimated from galaxy rotation curves. I am not sure how they come to the 30% figure rather than 25% figure but I assume it is to do with the difference between the influence of mass energy density in the form of rest mass and mass energy density in the form of radiation and motion. This difference is seen in different curvatures of a mass dominated universe and a radiation dominated universe with the same mass energy density. An alternative explanation is that one of the figures was given by a different author using less up to date data, but you mention that the two figures accompany each other suggesting they were given by the same author in the same text. Can you provide a quote to demonstrate that?

mysearch said:
...
Another good point that I need to consider. Does the statement imply that a clock in a hollow cavity surrounded by a uniform shell would feel no gravitational acceleration, but would still be subject to time dilation?

Yes! Exactly! :)
 
  • #143
Blurring the lines, I think. Observational evidence still implies a finite universe, IMO.
 
  • #144
Response to #142 & ~143

Hi Chronos: Could I ask what you would briefly list as the top observational evidence that supports a finite universe and what % confidence you have in this evidence?

#142: An alternative explanation is that one of the figures was given by a different author using less up to date data

Hi Kev: My apologises, you were right, I did actually get the information from different sources, so your explanation is probably right. However, my understanding of the dark matter issue was that it was still subject to verification. I have listed the following questions simply for clarification:

o As I understand it, dark matter has been speculated based on the observation of a number of gravitational anomalies, i.e. rotation anomalies in spiral galaxies to gravitational lensing around unseen objects?

o The first candidate were called MAssive Compact Halo Objects (MACHOs) which consisted of Jupiter-sized planets, brown dwarf stars, faint low-mass stars, white dwarf stars and even black holes. However, this idea would only account for a fraction of the dark matter required to explain all the previous anomalies?

o I understand that Weakly Interacting Massive Particles (WIMPs) is now the front-runner for the missing matter, which corresponds to the description of Cold Dark Matter? However, the existence of WIMPs has not yet been verified

Originally Posted by mysearch
Does the statement imply that a clock in a hollow cavity surrounded by a uniform shell would feel no gravitational acceleration, but would still be subject to time dilation?

Yes! Exactly! :)
On a quite expansive note, although still within the scope of the question about the universe being finite or infinite, there was a poll in this forum about the universe being a black hole. I believe the basis of this speculation is linked to the fact that current mass-density of the universe is approximately of the right order to create an event horizon at about the same size of the ‘visible universe’. Note, as I understand it, this mass-density corresponds to normal mass, not dark matter or dark energy, so some questions:

o Would dark matter or dark energy affect the radius of the speculated event horizon?

o Would this conceptual black hole universe have a centre of gravity?

o Would your caveat to Newton Shells apply, i.e. do we really understand the meaning of time within a black hole to evaluate the scope of time dilation?

Apologises if these questions appear to becoming overly speculative, but they are not being forwarded as any sort of proposal and they did seem to be a logical extrapolation of some other discussions already taking place in this forum.
 
  • #145
I have always been told the universe is expanding faster than C. Isn't the expanding space rather than moving galaxies thing just to satisfy the hypothesis that mass cannot move faster than C?
 
  • #146
Yes.

If the universe wasn't expanding at or faster than c, wouldn't we be able to the edge of the universe?
 
  • #147


mysearch said:
Hi Chronos: Could I ask what you would briefly list as the top observational evidence that supports a finite universe and what % confidence you have in this evidence?

The latest observations combining supernova, cluster and WMAP CMB data centres on Omega = 1.02 with a error of about +/- 0.02 which means a flat universe (Omega =1.00) is not excluded but the data tends towards a closed universe, but it is a close call.

mysearch said:
o As I understand it, dark matter has been speculated based on the observation of a number of gravitational anomalies, i.e. rotation anomalies in spiral galaxies to gravitational lensing around unseen objects?

Yes, gravitational lensing is more important evidense for dark matter. The bullet cluster is a famous example that points towards evidense of dark matter of the WIMP variety.


mysearch said:
...
o The first candidate were called MAssive Compact Halo Objects (MACHOs) which consisted of Jupiter-sized planets, brown dwarf stars, faint low-mass stars, white dwarf stars and even black holes. However, this idea would only account for a fraction of the dark matter required to explain all the previous anomalies?
Yes.
mysearch said:
o I understand that Weakly Interacting Massive Particles (WIMPs) is now the front-runner for the missing matter, which corresponds to the description of Cold Dark Matter? However, the existence of WIMPs has not yet been verified
See above comment about the bullet cluster.

mysearch said:
Hi
On a quite expansive note, although still within the scope of the question about the universe being finite or infinite, there was a poll in this forum about the universe being a black hole. I believe the basis of this speculation is linked to the fact that current mass-density of the universe is approximately of the right order to create an event horizon at about the same size of the ‘visible universe’. Note, as I understand it, this mass-density corresponds to normal mass, not dark matter or dark energy, so some questions:

o Would dark matter or dark energy affect the radius of the speculated event horizon?
Yes it would. All mormal matter and dark matter contribute to the density and gravitational effect. Dark energy contributes an antigravity effect. Certainly significant dark energy would exclude the concept of the universe being a black hole. One thing that should be considered in discussions of the universe as a black hole is that in a dynamic situation where all the mass is moving outward then the Schwarzschild radius is not simply R=2GM/c^2. That is the simplistic statc solution. How gravity acts on moving objects is more complicated. This is clearly seen in the coordinate spedd of light of a photon falling towards a black hole. The photon decelerates as it falls c'=c*(1-2GM/R/c^2) while a static object released near the black accelerates. Clearly there is velocity component to how gravity acts on a falling object. If the velovity at a given radius is below a certain critical value gravity accelerates the object and above the critical velocity it decelerates the object. (I am talking about coordinate measurements and not proper measurements).

mysearch said:
o Would this conceptual black hole universe have a centre of gravity?

Depends on whether you want to think in 4D or good old 3D ;)

mysearch said:
...
o Would your caveat to Newton Shells apply, i.e. do we really understand the meaning of time within a black hole to evaluate the scope of time dilation?

Some people say we cannot understand the physics inside a black hole because when we look at time and distance in proper measurements they are all imaginary numbers for R<Rs and at the singularity at the centre of a black hole the energy/mass density is infinite and doing math with infinite values is very difficult. The conventional interpretation is that the problems go away if we look at things in terms of proper measurements for a falling observer. The proper time of a falling observer is always one second per second. A fallng observer using his own clock can not detect time dilation and would not notice if time stopped or even reversed his own clock always ticks at one second per second as far as he is concerned. Personally, I think too much emphasis is placed on proper measureents as they tell us very little. For example in SR the proper length of a moving object is always it s rest length and the proper clock rate of a moving observer is always it rest clock rate. In other words if we only look at proper time in SR there is no such thing as time dilation and length contraction. Time dilation and length contraction only come about by comparing measurements of observers with different reference frames. That is a coordinate measurement. In GR and analysis of black holes, for some reason they choose to ignore coordinate measurements and concentrate only on proper measurements. I believe that is the wrong approac. I have shown in other posts that while the proper measurements below the event horizon are imaginary the coordinate measurements are real and so the coordinate measurements are valid. From that viewpoint, coordinate measurements show that a singularity can not form at the centre of a black hole, but I should add that is not the conventional viewpoint. Some papers that look at black holes from a quantum point of view tend to agree that singularities do not form in black holes and while that is not yet the accepted view, I detect a momentum of cutting edge opinion in that direction.
 
  • #148
I thought I'd add this, to me, the most intriguing thing about the universe is that you can look up into the sky and know that there lies only one solution.
 
  • #149
Response to #147

Kev, thanks for your response, I appreciate the clarifications on the dark matter issues. I am not really questioning the data, but wanted to see where people are currently defining the ‘limits of inference’.

Yes it would. All normal matter and dark matter contribute to the density and gravitational effect. Dark energy contributes an antigravity effect. Certainly significant dark energy would exclude the concept of the universe being a black hole.

On the assumption that dark energy accounts for 75% of the energy density, I guess the consensus rejects any sort of black hole speculation?

Depends on whether you want to think in 4D or good old 3D ;)

It is not always clear to me what people are exactly inferring when they use the term 4D, e.g. 3-D space plus time or some form of curved finite - but infinite universe etc.

The conventional interpretation is that the problems go away if we look at things in terms of proper measurements for a falling observer. The proper time of a falling observer is always one second per second.

Time dilation and length contraction only come about by comparing measurements of observers with different reference frames. That is a coordinate measurement. In GR and analysis of black holes, for some reason they choose to ignore coordinate measurements and concentrate only on proper measurements.

I also have some problems in this area as well, but they may differ from yours. When I looked at the arguments relating to coordinate singularity at an event hole, e.g. Gullstrand-Painleve, I couldn’t help feel that it solved the problem only by not looking at it. What I mean is that it just appears to look at local proper time and ignores the implication on relative time in all other frames of reference. However, we are probably digressing into another topic.

Anyway, I shall now do some more reading based on all the information supplied. Thanks for the help.
 
  • #150
epkid08 said:
I thought I'd add this, to me, the most intriguing thing about the universe is that you can look up into the sky and know that there lies only one solution.

Gödel's incompleteness theorems can be paraphrased as no non trivial theory (solution) can be both consistent and complete. In other words you can look up at the sky and know it is not possible to have a single solution for the universe that is both consistent and complete


See http://en.wikipedia.org/wiki/Gödel's_incompleteness_theorems
 
  • #151
Do you really think there isn't a single solution? I don't think it will ever be complete, or consistent as far as human knowledge goes, but I think there does lie a single solution. That very fact is what intrigues me.
 
  • #152
sketchtrack said:
I have always been told the universe is expanding faster than C. Isn't the expanding space rather than moving galaxies thing just to satisfy the hypothesis that mass cannot move faster than C?

It is the gravitational expansion of the space time metric, not movement of mass in space.
 
<h2>1. What is a finite universe?</h2><p>A finite universe is one that has a limited or measurable size or duration. This means that it has a definite beginning and end, and is not infinite.</p><h2>2. How do scientists determine if the universe is finite?</h2><p>Scientists use various methods, such as measuring the curvature of space, to determine the size and shape of the universe. They also study the distribution of matter and energy within the universe to understand its overall structure.</p><h2>3. Does a finite universe make sense in the context of the Big Bang theory?</h2><p>Yes, the Big Bang theory suggests that the universe began as a singularity and has been expanding ever since. This supports the idea of a finite universe with a definite beginning.</p><h2>4. What implications does a finite universe have for the future of our universe?</h2><p>If the universe is finite, it means that it will eventually reach an end point. This could have implications for the fate of the universe, such as whether it will continue to expand or eventually collapse.</p><h2>5. Are there any theories or evidence that suggest the universe is infinite instead of finite?</h2><p>There are some theories, such as the Steady State theory, that propose an infinite and unchanging universe. However, current evidence, such as the expansion of the universe and the cosmic microwave background radiation, supports the idea of a finite universe.</p>

1. What is a finite universe?

A finite universe is one that has a limited or measurable size or duration. This means that it has a definite beginning and end, and is not infinite.

2. How do scientists determine if the universe is finite?

Scientists use various methods, such as measuring the curvature of space, to determine the size and shape of the universe. They also study the distribution of matter and energy within the universe to understand its overall structure.

3. Does a finite universe make sense in the context of the Big Bang theory?

Yes, the Big Bang theory suggests that the universe began as a singularity and has been expanding ever since. This supports the idea of a finite universe with a definite beginning.

4. What implications does a finite universe have for the future of our universe?

If the universe is finite, it means that it will eventually reach an end point. This could have implications for the fate of the universe, such as whether it will continue to expand or eventually collapse.

5. Are there any theories or evidence that suggest the universe is infinite instead of finite?

There are some theories, such as the Steady State theory, that propose an infinite and unchanging universe. However, current evidence, such as the expansion of the universe and the cosmic microwave background radiation, supports the idea of a finite universe.

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