Exploring Space Expansion: Questions & Answers

In summary, this person is arguing that the expansion of space is an illusion due to the expansion of matter.
  • #71
Hi Jennifer,
MeJennifer said:
That is actually not true under GR. Two masses of 1kg closing in on each other due to gravitation will slowly decrease their total rest mass. Except when they are separated infinitely far from each other their total mass will be less than 2kg.
Let's be very careful about what you say isn't true. In the example you describe, I did not say that the combined masses did or did not decrease as they approach each other. I said only that their total energy in GR is invariant as they approach each other and after they collide, as judged by a far distant observer. No net energy is gained or lost in this (initially) two-object system.

Jon
 
Space news on Phys.org
  • #72
MeJennifer said:
That is actually not true under GR... Two masses of 1kg closing in on each other due to gravitation will slowly decrease their total rest mass. Except when they are separated infinitely far from each other their total mass will be less than 2kg.
So it is true under GR since this is about what jonmtkisco said :smile: The mystery (if there is any in it) is solved by noticing that while the total energy (or inertial mass) is conserved in GR (contrary to opinions of some mathematicians who because of their exact minds can't stomach this fact and the expansion of the universe at the same time, in which they are of course right), the "missing" mass is there in a form of kinetic energy of those masses. And all of it might be easily verified by just taking a derivative with respec to displacement, which will then show, white on black (if it is done with a chalk on a blackboard), all parts of total energy of the particle, and also the so called "gravitational force", since "force" is [tex]-d(mc^2)/dx[/tex], in which case [tex]mc^2[/tex] (actually it is [tex]mc^2\sqrt{g_{00}}[/tex] to be exact but [tex]\qrt{g_{00}[/tex] is almost 1) must be the potential energy that some people call "gravitational".

As an off topic remark I'd like to add that apparently I was right in my discussion with the head of our Gravitation and Cosmology Dept. who maintained that GR has to be reserved for PhD students only, since the regular physics students are to stupid to understand the curvature of space. My opinion was that people interested in physics need to know all the truth (that is available at the time) from the very beginning since only then they might be able to discover new things without necessity of wasting many years on unlearning what they "know" but it ain't so, as I had to, believing in things that now I know were not physics but math only and therefore not true. Einstein, who might have had some experience in those matters, said: "As far as the laws of mathematics refer to reality, they are not certain, as far as they are certain, they do not refer to reality" which roughly means that one can get only a trivial thruths (2+2=4) from math but non trivial truths can be found only through experiments, and, "If you are out to describe the truth, leave elegance to the tailor" (quote by the same author). Yet the GR has been constructed from "elegant" math and this elegant math said that the universe is expanding. The point of all of this is that a physicist must never believe in math that is not supported experimentally or observationally. And another point, which I see in this forum that some people interested in physics can think, which was my point in my discussion when I proposed to teach physics of GR from the first year of physics since it is even simpler that Newtonian math that assumes a mysterious and unobserved so far "gavitational attraction". Unfortunately the proposal was rejected by professors who teach the math of GR.
 
  • #73
Response to #68

#68: Frankly I do not see how physical interpretations of spacetime (curved or not) are going to be relevant here. Fact is gamma does not apply to curved spacetimes except locally.

The relevance is to the questions raised in #65. I am assuming that there is a physical interpretation to the assertion that spacetime is curved. If so, I would appreciate some ‘helpful’ clarification of the physical causes and scale of the effect in-line with current measurements rather than what appears to be a throwaway soundbite.

As a clarification, in #65, I simply tried to list some possible factors, which may or may not contribute to spacetime curvature. Given my statements about the localised effects of gravitation in an expanding k=0 homogeneous universe, without a centre of gravity, I was not asserting anything about the scope of [tex][\gamma][/tex]. The root of my confusion is that most references imply mass-gravity to be the cause of ‘local’ spacetime curvature, but the gravitation effects on the very large scale seem to be more ambiguous.

In part, my questions were triggered by, what I took to be, an outline of the concept of parallel transport by Garth in #61 associated with the discussion of the conservation of energy and momentum.

#61: The problem in GR is introduced, by space-time curvature. Energy is the time component of a particle's energy-momentum vector, how do you transport a vector across curved space time?

Presumably, the complexity of this issue is a direct function of the scale of the curvature and this is why I was trying to get some sort of physical interpretation to its cause and the scale of the curvature.
 
  • #74
Quick response to #72

#72: GR has to be reserved for PhD students only, since the regular physics students are to stupid to understand the curvature of space. My opinion was that people interested in physics need to know all the truth...

In-line with an earlier exchange, while I may well be too stupid, or should I say 'cerebrially challenged' in this politically correct world, to understand all the implications of GR and its maths; I would like to think that it was part of the ethos of the PF to, at least, try to help us, the 'cerebrially challenged' , onto the ‘path of enlightenment’, even if we might subsequently falter along the way.:smile:
 
Last edited:
  • #75


mysearch said:
In part, my questions were triggered by, what I took to be, an outline of the concept of parallel transport by Garth in #61 associated with the discussion of the conservation of energy and momentum.

#61: The problem in GR is introduced, by space-time curvature. Energy is the time component of a particle's energy-momentum vector, how do you transport a vector across curved space time?

Presumably, the complexity of this issue is a direct function of the scale of the curvature and this is why I was trying to get some sort of physical interpretation to its cause and the scale of the curvature.

This problem is solved by an assumption that from the point of view of parallel transport the spacetime is "flat" (no change in direction of energy-momentum vectors). For this type of faltness of spacetime neither space not time needs to be flat (Euclidean), only their combination the spacetime. That's why we say that spacetime is curved or flat depending on which aspect of it we are talking about, and most people understand why it happens though it might be confusing and then you should ask if you see an inconsistence before thinking that all GR people are idiots (even if http://geocities.com/jim_jastrzebski/sci/feynman.htm" :smile:).
 
Last edited by a moderator:
  • #76
Response to #75

Jim: thanks for the response, but was a little puzzled by the inference at the end of the following quote:
That's why we say that spacetime is curved or flat depending on which aspect of it we are talking about, and most people understand why it happens though it might be confusing and then you should ask if you see an inconsistence before thinking that all GR people are idiots.

I don’t think I ever implied `any` GR people were idiots. In fact, I thought my comments in #76 made it clear that I accepted the limitations of my own knowledge in this area. :confused: However, I would confess to having some empathy with the Feynman reference. :smile: However, my main issue is still with securing a better overall understanding of the implied spacetime curvature on the scale of the universe.
This problem is solved by an assumption that from the point of view of parallel transport the spacetime is "flat" (no change in direction of energy-momentum vectors). For this type of flatness of spacetime neither space not time needs to be flat (Euclidean), only their combination the spacetime.
Given the inference that SR is associated with Minkowski flat spacetime, I assume the source of curvature lies within GR, which we might summarise in the form of the Wheeler quote:
Matter tells space-time how to curve, and curved space tells matter how to move.

However, this only seems to explain localized spacetime curvature. The point I was really trying to clarify was based on the assumption of a homogeneous k=0 universe with no center of gravity. What causes curvature, if any, on this scale?
 
  • #77
Note that k is not a quantity pertaining to spacetime but instead a quantity pertaining to a particular coordinate chart.

In FRW models (containing matter) spacetime is not flat. In FRW models the Weyl curvature tensor vanishes while the Ricci curvature tensor does not. In FRW models there is actually no such thing as empty space as it models a pressureless perfect fluid. Which makes the often made statements that "space expands" or the "space between objects increases" rather out of place.
 
Last edited:
  • #78
Response to #77

Note that k is not a quantity pertaining to spacetime but instead a quantity pertaining to a particular coordinate chart.

Thanks, point duly noted, but is it still correct to say that [k=0] implies a spatially flat universe?

In FRW models (containing matter) spacetime is not flat. In FRW models the Weyl curvature tensor vanishes while the Ricci curvature tensor does not. In FRW models there is actually no such thing as empty space as it models a perfect fluid. Which makes the often made statements that "space expands" or the "space between objects increases" rather strange.

The following bullets are purely to help me infer some physical meaning onto the introduction of Weyl and Ricci tensors. Further clarification of my simplistic definitions welcomed:

- If we equate a unit of 4-dimensional spacetime to a sphere, it has the ability to change its volume and its shape.

- The Ricci tensor describes how the volume changes in any given direction.

- The Weyl tensor describes how it changes its shape.

- Based on your FRW description, if the Weyl tensor vanishes, i.e. goes to 0?, while the Ricci tensor does not, does our sphere only change its volume, but not its shape?

- This suggests an expanding model of the universe, which does not distort in shape as it expands. Is this correct as you seem to be refuting the notion of space expanding?

- However, don’t these tensors only reflect the change, not the reason for the change?

Realise the whole issue of expansion is another ‘bag of worms’ but, at this stage, I still just want to get some physical explanation of what causes spacetime on the scale of the universe to be curved, if this is what LCDM cosmology is actually implying. However, I appreciate the input and would welcome any further clarifications.
 
  • #79


mysearch said:
I still just want to get some physical explanation of what causes spacetime on the scale of the universe to be curved.
Mass and energy curves spacetime. Only spacetimes that have no mass and energy are flat.
 
  • #80
Response to #79

Mass and energy curves spacetime. Only spacetimes that have no mass and energy are flat.

OK, that is helpful, as I had really only been focused on mass. So is it correct to infer that the mass-density of the universe, ignoring energy for the moment, cannot appreciably curve spacetime on the scale of the universe given my basic homogeneous, no centre of gravity assumptions?

Classically, we often infer energy associated with mass in the form of kinetic (+) and potential (-) energy, but from the perspective of the conservation of energy these two forms are thought of as adding up to zero?

Therefore, not sure how this is accounted within any total mass-energy density?

While I know there is much speculation about dark energy, possibly accounting for 75% of the total mass-energy density, I thought this form was thought to have negative pressure. It is unclear to me as to what assumptions are being made about its effects on spacetime curvature of the universe as a whole?
 
  • #81
Garth said:
Hi kev.

You have to define how you measure energy and then how to compare that measurement between different coordinate systems.

The problem in GR is introduced, by space-time curvature.

Energy is the time component of a particle's energy-momentum vector, how do you transport a vector across curved space time?

Consider the surface of a cylinder with a vector in the tangent plane at one point on that surface.

Now transport the vector over the surface.

If you go around the curved surface the tangent plane and the vector being parallel transported in it will turn, so although the vector's overall length does not change a coordinate based measurement of its components will in general change.

However it we move up the surface parallel to the axis of the cylinder, where there is a symmetry, the vector will not turn. In this case the components will not change, they will be conserved under the translation.

If the vector is energy momentum and the axis of the cylinder represents the time axis of a space-time surface then there is a time-like Killing vector and the 'axis' component that is conserved is energy.

I hope this helps.

Garth

Did you mean a sphere?

When a tangent vector is parallel transported on a cylindrical surface keeping it tangent to the surface it does not turn. When tangent vector A is parallel transporting to tangent vector B then if they are parallel the same is true whatever route A is transported via to get to B. There is no problem with defining parallel on a cylindrical surface and essentially it can be thought of as flat spacetime. The cylindrical surface can be cut and rolled out flat with no distortion.

The same is not true for a sperical surface. There is no way to "flatten out" the surface without distortion. Parallel transport on a cylindrical surface does indeed cause the tangent vector to turn and when comparing tangent vector A with B the comparison varies depending upon the route taken by A. That is one way of defining "curved space" and showing that a cylinder has extrinisic curvature but not intrinsic curvature. The sphere has intrinsic curvature and that defines curved space.

By the way, I thought of a method for comparing tangent vectors on a sphere to see if they are parallel. It requires marking out a grid on the sphere in the same way we put lines of longitude and latitude on the global map of the Earth. The latitude lines are great circles or meridians radiating out from the North pole and the longitude lines are parallel to the equator.
The method is applied to a reference vector that is co-transported with vector A and is initially parallel to vector A. Vector A is parallel transported in the normal way and the co-transported reference vector has to obey these 3 simple rules.

1) When transporting the reference vector along a line of longitude for every degree increase in longitude, rotate the reference vector one degree in the opposite direction relative to parallel transported vector A.

2) When transporting the reference vector along a line of latitude do not turn the reference vector relative to parallel transported vector A.

3) The reference vector and parallel transported vector A must remain in the tangent plane of the sphere at all times.

When parallel transported vector A arrives at the location of vector B, then if the reference vector is parallel to vector B, then A and B were initially parallel. If I got it right, then this statement will be true for any route taken by A using these rules.

A simple example that might be easier to visualise would be to imagine looking down from high above the North pole. If a vector being parallel transported around the equator appears to be have gone 90 degrees anti-clockwise around the North pole then its reference vector should be rotated 90 degrees clockwise during the transportation. When the vector is transported from the equator to the North pole then the vector and its reference vector should be parallel transported in the normal way.
 
  • #82


Hi mysearch,
mysearch said:
So is it correct to infer that the mass-density of the universe, ignoring energy for the moment, cannot appreciably curve spacetime on the scale of the universe given my basic homogeneous, no centre of gravity assumptions?
Are you asking about spacetime curvature or spatial curvature? They are very different things. Anywhere there is gravity (and optionally pressure) there is spacetime curvature, they are defined to mean the same thing. Both gravity and pressure are significant on the scale of our universe, and do not equally offset each other in the current era, so by definition there is appreciable "net" cosmic spacetime curvature. At a particular earlier era (around 7Gy), gravity and pressure were exactly in balance, so at that time the "net" cosmic spacetime curvature was zero. During that brief period, the cosmic expansion essentially coasted, with approximately zero net acceleration.

On the other hand, the question of whether the universe is characterized by cosmic spatial curvature is a subject of much observational and theoretical analysis right now. Currently the error bars in our measurement techniques do not enable us to discern whether the curvature is different from zero. For most analytical purposes, it is reasonable to start with the assumption that the universe is spatially flat.
mysearch said:
Classically, we often infer energy associated with mass in the form of kinetic (+) and potential (-) energy, but from the perspective of the conservation of energy these two forms are thought of as adding up to zero?

Therefore, not sure how this is accounted within any total mass-energy density?
When mass-energy density is used in calculations such as the Friedmann equations, neither the kinetic energy of expansion nor the potential energy of cosmic position are included, because they are not GR concepts. Only rest mass and pressure are counted. So the calculations count the 3 forms of rest mass: matter, free radiation, and the rest mass of dark energy/cosmological constant; and 2 forms of pressure: the negative pressure of dark energy/cosmological constant, and the positive pressure of free radiation (the latter currently being insignificant).
mysearch said:
While I know there is much speculation about dark energy, possibly accounting for 75% of the total mass-energy density, I thought this form was thought to have negative pressure. It is unclear to me as to what assumptions are being made about its effects on spacetime curvature of the universe as a whole?
The negative pressure of dark energy/cosmological constant is accounted for in the Friedmann equations, along with the 3 forms of rest mass. For the cosmological constant, its negative pressure = its own rest mass. The Friedmann equations multiply pressure by 3, so regarding the cosmological constant, in effect 1X of its negative pressure goes to offset the gravitational deceleration effect of own its rest mass, and the remaining 2X of its pressure goes toward overcoming the gravitational deceleration caused by matter and then accelerating the overall expansion rate. At the time in the history of the universe when the acceleration component first exceeded the gravitational deceleration component, the shift in the balance of the homogeneous cosmic spacetime curvature caused the sign of expansionary acceleration to reverse.

The Friedmann equations are cleverly designed so that the cosmological constant itself does not affect the spatial curvature of the universe. If the universe was spatially flat before the cosmological constant became dominant, the cosmological constant will not change that. The same is true for the extra gravity caused by the positive pressure of free radiation, which dominated the very early universe. It caused a very high deceleration rate, but did not affect spatial flatness.

Jon
 
Last edited:
  • #83
Response to #82

Are you asking about spacetime curvature or spatial curvature? They are very different things. Anywhere there is gravity (and optionally pressure) there is spacetime curvature, they are defined to mean the same thing. Both gravity and pressure are significant on the scale of our universe, and do not equally offset each other in the current era, so by definition there is appreciable "net" cosmic spacetime curvature. At a particular earlier era (around 7Gy), gravity and pressure were exactly in balance, so at that time the "net" cosmic spacetime curvature was zero. During that brief period, the cosmic expansion essentially coasted, with approximately zero net acceleration. On the other hand, the question of whether the universe is characterized by cosmic spatial curvature is a subject of much observational and theoretical analysis right now. Currently the error bars in our measurement techniques do not enable us to discern whether the curvature is different from zero. For most analytical purposes, it is reasonable to start with the assumption that the universe is spatially flat.

Jon: Thanks, this is the most concise and coherent summary of the issues I seen, hence the replication in quotes. However, I wanted to see if I could distill a few further facts from your summary:

- Gravitation causes spacetime curvature, as does pressure, presumably in the form of dark energy? Gravity is associated with negative potential energy, so is pressure (dark energy) considered as energy per unit volume rather than in terms of force per unit area? If so, is it considered positive in respect to gravitational potential energy? If these are the two significant energy factors operating on the scale of the universe do you think they obey the conservation of energy?

- [k=0] is an approximation of the measured spatial curvature/flatness of the universe. However, what would cause spatial curvature independent of the spatial components of spacetime curvature linked to gravity and pressure? While it could just be said that the geometry of space was curved, we usually like to have a reason, e.g. there are no straight lines in quantum mechanics.

- I believe I understand the general concept of spacetime curvature in GR on a local system, e.g. galaxy, however, my issue, in the context of large-scale cosmology, was primarily linked to the assumption of a homogeneous model with no centre of gravity. What is spacetime curving around in a mass-gravity only model?

- If we add pressure (dark energy) to the mix linked to the assumption that it represents energy per unit volume, do we also conclude that this pressure has an effective mass, e.g. [tex][m=E/c^2][/tex], and therefore an anti-gravitational effect by virtue of an opposite sign? As a side issue, if gravity is associated with negative potential energy and dark energy acts in the opposite direction, would it be correct to say that this energy is positive not negtaive?

- On the assumption of a 4% matter, 23% cold dark matter and 73% dark energy split, do we conclude that 27% of the universe is trying to collapse, while 73% is trying to expand? Is there any assumption about the relative strength of these effects, as it would appear that expansion should win hands down? I don’t understand how dark energy changes with time?

- If I consider these effects independent of time, I simply perceived expansion and contraction linked to pressure and gravity, i.e. no specific implication of curvature. Of course, if I introduce time, then the expansion of each unit volume of space as a function of time does lead to the implication of a curved path, at least, with respect to light. As such, two parallel light beams diverge in an expanding universe and converge in a contracting universe, is this the root of the definition of spacetime curvature, at least, on the scale of the universe?

- As a slight tangential point, if light travels at [c] at any measured instance in space and time, but the path followed by the light beam is subject to expansion over time, does this imply that light never conforms to [c=s/t], if is a curved geodesic resulting from the expansion of space with time? As a result, the measure value of the speed of light will always exceed [c] as during the time it takes to travel any distance, as the space over which its has traveled has expanded?

- While I don’t want to confuse the discussion by re-introducing the concept of a centre of gravity, this issue has been raised in the thread below and would presumably be a significant factor in any model?
https://www.physicsforums.com/showthread.php?t=235046
 
Last edited:
  • #84


jonmtkisco said:
At a particular earlier era (around 7Gy), gravity and pressure were exactly in balance, so at that time the "net" cosmic spacetime curvature was zero.
I have trouble with this statement.

When there is gravity and pressure there is spacetime curvature.

What do you mean by "in balance" and what is cosmic spacetime curvature as opposed to spacetime curvature?
 
  • #85


Hi Jen,
MeJennifer said:
What do you mean by "in balance" and what is cosmic spacetime curvature as opposed to spacetime curvature?
When the gravitational deceleration is exactly balanced by the negative pressure acceleration of Lambda, then the universe expands at a constant, coasting rate. That is, at the same rate it would if there were NO gravity and NO pressure. The acceleration parameter = 0.

I think that means that the cosmic spacetime curvature is temporarily at 0. "Cosmic" meaning the spacetime curvature above the scale of matter homogeneity, > 100 Mpc.

If you believe there is "net" large scale spacetime curvature at that balance time, please explain.

The exact balance time lasted only an instant, although it lasted longer as an approximation.

Jon
 
  • #86


Hi mysearch,
mysearch said:
- is associated with negative potential energy, so is pressure (dark energy) considered as energy per unit volume rather than in terms of force per unit area?
As I said, potential energy is not a GR concept, so it is not considered at all in GR. The negative pressure of the cosmological constant is considered as energy per unit volume.
mysearch said:
If these are the two significant energy factors operating on the scale of the universe do you think they obey the conservation of energy?
Potential energy is not a GR concept. And as I said, the Friedmann universe does not conserve energy.
mysearch said:
- [k=0] is an approximation of the measured spatial curvature/flatness of the universe. However, what would cause spatial curvature independent of the spatial components of spacetime curvature linked to gravity and pressure?
Spatial curvature occurs only when a large region of the universe does not expand at exactly the Newtonian escape velocity of its mass/energy contents. In other words, it's a mismatch between expansion speed and the mass-energy density. As I said, the negative pressure of Lambda and the positive pressure of free radiation do not cause a change in spatial curvature.
mysearch said:
- I believe I understand the general concept of spacetime curvature in GR on a local system, e.g. galaxy, however, my issue, in the context of large-scale cosmology, was primarily linked to the assumption of a homogeneous model with no centre of gravity. What is spacetime curving around in a mass-gravity only model?
I don't understand the question.
mysearch said:
- If we add pressure (dark energy) to the mix linked to the assumption that it represents energy per unit volume, do we also conclude that this pressure has an effective mass, e.g. [tex][m=E/c^2][/tex], and therefore an anti-gravitational effect by virtue of an opposite sign?
As I already said, the cosmological constant has a gravitational mass-energy equal to the negative of its negative pressure.
mysearch said:
As a side issue, if gravity is associated with negative potential energy and dark energy acts in the opposite direction, would it be correct to say that this energy is positive not negtaive?
For the last time, potential energy is not a GR concept.
mysearch said:
- On the assumption of a 4% matter, 23% cold dark matter and 73% dark energy split, do we conclude that 27% of the universe is trying to collapse, while 73% is trying to expand? Is there any assumption about the relative strength of these effects, as it would appear that expansion should win hands down?
The ratio between matter and DE changes as a function of time. Right now it is believed to be .27:.73. In addition, the cosmological constant has negative pressure equal to the negative of 3x its gravitational mass-energy. So at the present time, DE dominates the expansion rate. But this was not always so.
mysearch said:
I don’t understand how dark energy changes with time?
Dark energy (in the form of the cosmological constant) is believed to be a fixed characteristic of the vacuum. Each cubic meter of vacuum contains a cosmological constant of about 6.7E-27 kg/cubic meter. So as the number of cubic meters in the observable universe has increased over its history, the total kg of cosmological constant has increased. Meanwhile, the amount of matter in the observable universe remained fixed. Eventually (at about 7Gy), the "weight" of cosmological constant in the observable universe began to exceed the weight of matter. By about 9Gy, the cosmological constant was the dominant expansion force, and the deceleration caused by matter had become insignificant by comparison.
mysearch said:
- While I don’t want to confuse the discussion by re-introducing the concept of a centre of gravity, this issue has been raised in the thread below and would presumably be a significant factor in any model?
The existence of a center of gravity would cause the cosmic gravitational force to vary in proportion to distance from the center. But since initial expansion velocity would also vary in proportion to distance from the center, all comoving galaxies would decelerate at the same proportion of their current velocity. As a result, I believe that the varying effect of gravity at different distances from the center would not be detectible, and would not cause a change in the matter homogeneity.

Jon
 
  • #87
Response to #86:

For the last time, potential energy is not a GR concept.

OK, I got the message loud and clear. I understand that GR does not used PE to explain gravity, however, I was not aware that it banned its use as a way of trying to visualise the conservation of energy issues. I am sure you can appreciate that trying to assimilate all the somewhat speculative issues being raised for anybody new to this subject requires a bit of time and some reflection from more than one perspective. However, if you feel you have already addressed my question, then please simply ignore it.
And as I said, the Friedmann universe does not conserve energy.

Sorry, but I could not find where you explicitly made this point before. Is it related to the implication that GR does not always conserve energy? I am raising this issue because there are derivations of the Friedmann and Fluid equations that seem to have the conservation of energy as a root assumption.
Dark energy (in the form of the cosmological constant) is believed to be a fixed characteristic of the vacuum. Each cubic meter of vacuum contains a cosmological constant of about 6.7E-27 kg/cubic meter. So as the number of cubic meters in the observable universe has increased over its history, the total kg of cosmological constant has increased. Meanwhile, the amount of matter in the observable universe remained fixed.

This was a helpful clarification. However, is the value [tex]6.7E-27kg/m^3[/tex] quoted associated with the critical density [tex][\rho_c][/tex] normally inferred from Friedmann’s equation, i.e. [tex]\rho_c = 3H^2/8 \pi G[/tex]?
So the calculations count the 3 forms of rest mass:
- matter, free radiation & dark energy
and 2 forms of pressure:
- negative dark energy & positive free radiation

I have paraphrased the quote above from #82, but wanted to check whether matter included CDM? However, as you highlighted, dark energy also has an associated mass with corresponding gravitational implications, as well as being the pressure (energy per unit volume) that drives expansion. However, could I clarify the use of ‘pressure [P]’ and the ‘cosmological constant [itex][\Lambda][/itex]’ in the following form of the acceleration equation?

[tex] \frac {\ddot a}{a} = - \frac{4 \pi G}{3} \left ( \rho + \frac {3P}{c^2} \right ) + \frac {\Lambda c^2}{3}[/tex]

If I describe dark energy in terms of a negative pressure [P] does this effectively negate the need for the [tex][\Lambda][/tex] term, as its units, i.e. [tex]m^{-2}[/tex], do not really seem indicative of pressure? The following form of the equation above simply removes all constant values and [tex][\Lambda][/tex] to highlight the dependency on just [tex][\rho][/tex] and [P]:

[tex] \frac {\ddot a}{a} = - \rho - (3P) [/tex]

Clearly, for acceleration to be expansive, pressure has to be negative and as you pointed out some of the negative pressure must overcome the effective gravitational mass of dark energy itself. However, what seems even stranger is the fact that the dark energy, which is the energy per unit volume that expands space, does not get ‘diluted’ in the process, i.e. the suggestion appear to be that it remains constant. If I have interpreted this correctly, it gives the impression that mass and energy are being `created` in the process or, at least, tapping into some other source, i.e. zero point energy/vacuum energy.
The existence of a center of gravity would cause the cosmic gravitational force to vary in proportion to distance from the center. But since initial expansion velocity would also vary in proportion to distance from the center, all comoving galaxies would decelerate at the same proportion of their current velocity. As a result, I believe that the varying effect of gravity at different distances from the center would not be detectible, and would not cause a change in the matter homogeneity.

In part, this issue is also being discussed in another thread. I have posted a query against this position, which can be accessed via the following link. https://www.physicsforums.com/showthread.php?p=1844506#post1844506

However, one point that I would like to raise in this thread is simply a level of surprise that nobody has challenged the assumption of a centre of gravity, as I thought this was not normally accepted as part of the standard model?
 
  • #88


jonmtkisco said:
At a particular earlier era (around 7Gy), gravity and pressure were exactly in balance, so at that time the "net" cosmic spacetime curvature was zero. During that brief period, the cosmic expansion essentially coasted, with approximately zero net acceleration.

This isn't correct. Zero acceleration is not sufficient for zero spacetime curvature. For a spatially flat universe that has zero scale factor acceleration, zero scale factor velocity, (i.e., zero expansion) is a necessary condition for zero spacetime curvature.

For example, see the expression for the curvature scaler given in

http://en.wikipedia.org/wiki/Friedmann_equations.

If the curvature scalar is non-zero, then the Riemann curvature tensor is non-zero.
 
  • #89


Hi George,
George Jones said:
If the curvature scalar is non-zero, then the Riemann curvature tensor is non-zero.
Good catch. I was thinking about it as if the balance point could be held constant, but of course it cannot. If mass or pressure is present, spacetime curvature changes continuously, so as a function of moving time it is never zero.

Still, there is an instant when the deceleration parameter = 0.

How about a universe where the Lambda equation of state is -1/3, which coasts in perpetuity? In that case is the spacetime curvature zero?

Jon
 
Last edited:
  • #90


jonmtkisco said:
How about a universe where the Lambda equation of state is -1/3, which coasts in perpetuity? In that case is the spacetime curvature zero?
No, this one can't be exactly zero spacetime curvature either. Even with an equation of state of [tex]\omega = -1/3[/tex], the universe will evolve over time, as expansion dilutes the density of matter, and Lambda comes to dominate over matter. It will approach true "coasting" only at late times. I believe it will asymptotically approach zero spacetime curvature at late times despite retaining a positive expansion velocity.

Jon
 
  • #91


Hi myseach,
mysearch said:
Is it related to the implication that GR does not always conserve energy? I am raising this issue because there are derivations of the Friedmann and Fluid equations that seem to have the conservation of energy as a root assumption.
The Friedmann equations do conserve energy at least for a spatially flat model with zero Lambda.
mysearch said:
This was a helpful clarification. However, is the value [tex]6.7E-27kg/m^3[/tex] quoted associated with the critical density [tex][\rho_c][/tex] normally inferred from Friedmann’s equation, i.e. [tex]\rho_c = 3H^2/8 \pi G[/tex]?
Yes, you use the Friedmann equations to calculate it, using the estimated figures for matter and Lambda density, as a function of time. An easy way to calculate it is to run the Friedmann equations into the arbitrarily distant future when Lambda becomes the only significant component of the universe's mass-energy.
mysearch said:
I have paraphrased the quote above from #82, but wanted to check whether matter included CDM?
Yes it is; as you know the great majority of matter mass is believed to be dark energy.
mysearch said:
If I describe dark energy in terms of a negative pressure [P] does this effectively negate the need for the [tex][\Lambda][/tex] term, as its units, i.e. [tex]m^{-2}[/tex], do not really seem indicative of pressure? The following form of the equation above simply removes all constant values and [tex][\Lambda][/tex] to highlight the dependency on just [tex][\rho][/tex] and [P]:

[tex] \frac {\ddot a}{a} = - \rho - (3P) [/tex]
No, Lambda is in the equation for a reason, so you cannot simply exclude it.
mysearch said:
However, what seems even stranger is the fact that the dark energy, which is the energy per unit volume that expands space, does not get ‘diluted’ in the process, i.e. the suggestion appear to be that it remains constant. If I have interpreted this correctly, it gives the impression that mass and energy are being `created` in the process or, at least, tapping into some other source, i.e. zero point energy/vacuum energy.
The simplest concept for dark energy is the cosmological constant, and every cubic meter of vacuum comes with its own cosmological constant, so by definition it can never be diluted. On the contrary it helps to dilute and eventually dominate everything else.

The ongoing creation of additional space filled with its own (additional) Lambda seems to be a characteristic of both the "dust ball model" and standard cosmology, which suggests that indeed new energy is being constantly created. Perhaps one could also posit a model where the empty vacuum "outside" the dust ball has Lambda but does not expand in accordance with the de Sitter model. In which case the existing Lambda was always there and is not being newly created. But any such theory is entirely speculative. In any event, little satisfaction is gained by saying that infinite energy was "always there" instead of incremental energy being "newly created" with the passage of time.
mysearch said:
However, one point that I would like to raise in this thread is simply a level of surprise that nobody has challenged the assumption of a centre of gravity, as I thought this was not normally accepted as part of the standard model?
Standard cosmology readily admits that the lack of a center of gravity is a simplifying assumption, rather than a fact or theory which has been demonstrated to be highly likely. I believe it is a widely accepted assumption because of its mathematical simplicity (no "edge" effects) and philosophical elegance (cosmological principle), and because as a practical matter the observable characteristics of the universe so far have not depended on whether the assumption is correct.

Jon
 
Last edited:
  • #92
Response to #91:

Hi Jon,
Given the excessive length of my response in another thread, I will keep this one brief. Thanks for all the help, you given me a lot to think about, however, I now recognise the need do some more detailed reading based on what I hope is now a more ‘expansive’ perspective. Much appreciated.

P.S. Your last statement is very interesting, especially if nobody challenges it!
Standard cosmology readily admits that the lack of a center of gravity is a simplifying assumption, rather than a fact or theory which has been demonstrated to be highly likely. I believe it is a widely accepted assumption because of its mathematical simplicity (no "edge" effects) and philosophical elegance (cosmological principle), and because as a practical matter the observable characteristics of the universe so far have not depended on whether the assumption is correct.
 
Last edited:
  • #93


jonmtkisco said:
Standard cosmology readily admits that the lack of a center of gravity is a simplifying assumption, rather than a fact or theory which has been demonstrated to be highly likely. I believe it is a widely accepted assumption because of its mathematical simplicity (no "edge" effects) and philosophical elegance (cosmological principle), and because as a practical matter the observable characteristics of the universe so far have not depended on whether the assumption is correct. Jon

We base a great deal of the Big Bang on the cosmological principle. And it is indeed an excellent model by which to hash out the local nature of the universe. But it is based on limited data in pursuit of an complete description of a universe that always seems to have more in store than our descriptions can convey. To attempt to contrive a complete and sufficient view of the universe, rather than presuming our models to be local characterizations, is ill-advised in my view.

Across 40 orders of spatial magnitude the material universe has proven to be uniformly hierarchical, yet in all our cosmologies we humans like to terminate that hierarchy at the limits of our data (flat earth, crystal sphere, island universe, steady state, etc). Currently we choose to presume the the mere 2 orders of magnitude of homogeneous galactic clustering we see at the limits of our view are sufficient to completely characterize a potentially infinite universe. We do this even though we can easily find in excess of 14 orders of magnitude of homogeneity (water molecule in 10 cubic km of ocean) nested within the 40 orders of hierarchy we have already fully examined. To invest all our efforts in a model based on such a selective application of the data is poor science in my estimate.

The Big Bang is an idealized model of how the universe could work if the material hierarchy did somehow stop at the limits of our ability to examine it. Like the 19th century "Island Universe" model of the Milky Way, the Big Bang is a beautiful, comprehensive, ostensibly accurate model of how the universe would behave if the hierarchy did stop. But like every cosmology we ever devised, the limits we habitually place on the hierarchy have always proven to be false and the hierarchy has always persisted beyond them.

The advantage to presuming an ongoing hierarchy is to better address the anomalous data in the current model. Influences from a greater context often show up as anomalous data in the current model (Al Sufi's nebula, Hubble's red shift). It is just as likely that the questions of dark matter, dark energy and curvature of the universe are related to the material and energetic effects of the surrounding hierarchical context rather than strictly local variable adjustments in the current model.

Sure the Big Bang will be BIG, but it won't be "everything." There will always be more to the hierarchy than we can see from here, just as has always been the case. That's what the material and historical data both consistently indicate. If the cosmological principle is good science, then the hierarchical principle is better science.

-Mike
 
  • #94
Response to #93:

There are more things in heaven and earth, Horatio, than are dreamt of in your philosophy.
Hamlet by William Shakespeare: 16th Century
Hi Mike,
In many respects, I think you have eloquently summarised a valid view of, not only, the Big Bang model, but possibly science as a whole. This is not an anti-science or anti-establishment view, far from it, simply a recogniition of the reality of the endeavour and we all need to be reminded of this reality occasionally.
Concepts that have proven useful in ordering things can easily attain an authority over us such that we forget their worldly origin and take them as immutably truths. They are then rubber-stamped as a "sine-qua-non of thinking" and an "a priori given". Such errors often make the road of scientific progress impassable for a long time.
Albert Einstein: 20th Century
 
<h2>1. What is space expansion?</h2><p>Space expansion refers to the continuous growth of the universe, where galaxies and other celestial bodies are moving away from each other at an increasing rate. This expansion is driven by a force called dark energy, which makes up about 70% of the total energy in the universe.</p><h2>2. How do scientists study space expansion?</h2><p>Scientists study space expansion through various methods, such as measuring the redshift of distant galaxies, mapping the cosmic microwave background radiation, and observing the movements of supernovae. These methods help us understand the rate of expansion and how it has changed over time.</p><h2>3. Will space expansion eventually stop?</h2><p>Current scientific evidence suggests that space expansion will continue indefinitely, as the force of dark energy is expected to overpower the gravitational pull of matter. However, the rate of expansion may change over time, and it is still a topic of ongoing research and debate.</p><h2>4. What are the implications of space expansion?</h2><p>The implications of space expansion are vast and complex. It affects the structure and evolution of the universe, the formation of galaxies and stars, and the distribution of matter and energy. It also has implications for our understanding of fundamental physics and the fate of the universe.</p><h2>5. How does space expansion relate to the Big Bang theory?</h2><p>Space expansion is a key concept in the Big Bang theory, as it explains the origin and evolution of the universe. According to this theory, the universe began as a singularity and has been expanding ever since. The observed evidence of space expansion supports the Big Bang theory and helps us understand the early stages of the universe.</p>

1. What is space expansion?

Space expansion refers to the continuous growth of the universe, where galaxies and other celestial bodies are moving away from each other at an increasing rate. This expansion is driven by a force called dark energy, which makes up about 70% of the total energy in the universe.

2. How do scientists study space expansion?

Scientists study space expansion through various methods, such as measuring the redshift of distant galaxies, mapping the cosmic microwave background radiation, and observing the movements of supernovae. These methods help us understand the rate of expansion and how it has changed over time.

3. Will space expansion eventually stop?

Current scientific evidence suggests that space expansion will continue indefinitely, as the force of dark energy is expected to overpower the gravitational pull of matter. However, the rate of expansion may change over time, and it is still a topic of ongoing research and debate.

4. What are the implications of space expansion?

The implications of space expansion are vast and complex. It affects the structure and evolution of the universe, the formation of galaxies and stars, and the distribution of matter and energy. It also has implications for our understanding of fundamental physics and the fate of the universe.

5. How does space expansion relate to the Big Bang theory?

Space expansion is a key concept in the Big Bang theory, as it explains the origin and evolution of the universe. According to this theory, the universe began as a singularity and has been expanding ever since. The observed evidence of space expansion supports the Big Bang theory and helps us understand the early stages of the universe.

Similar threads

Replies
65
Views
4K
Replies
17
Views
2K
Replies
6
Views
1K
Replies
5
Views
1K
Replies
1
Views
759
Replies
7
Views
1K
Replies
42
Views
3K
Replies
25
Views
1K
Back
Top