Proving the Expansion of the Universe

In summary: So, in summary, this is what the evidence suggests: 1) We see galaxies moving away from us and superluminal galaxies which is not allowed by special theory of relativity 2) We see the motion of galaxies due to the expansion of space 3) The evidence for the expansion of space comes from the redshift of distant objects and the problems with reconciling causally-disconnected parts of the universe 4) There is evidence for the expansion of space from other fields of physics too, such as the Big Bang itself
  • #1
cosmoboy
65
0
Before asking a qusetion let me put first the statement of big bang cosmolgy:
"These are not galaxies which are going away from us in a fixed space, this is the space between galaxies which is opening up or stretching."

Now my question is: In both the cases (either space stretch or galaxies move) what we see is the motion of galaxies, I want to ask that how to prove that this is the space which is stretching ?

One answer could be that since we can see superluminal galaxies which is not allowed by special theory of relativity. So in order to expalin this we need the expansion of the space, because there is no upper limit on the rate of expansion of the space. Please let me know
what are other arguments.

thanks
 
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  • #2
cosmoboy said:
Now my question is: In both the cases (either space stretch or galaxies move) what we see is the motion of galaxies, I want to ask that how to prove that this is the space which is stretching ?

Here's a thought experiment for you. If the size of the Universe is unchanging, why aren't there as many galazies moving towards us as away from us? It's not physically possible for every galaxy to be moving away from us unless 1) We're special -or- 2) The Universe itself is expanding. This doesn't *prove* the Universe is expanding, but it's one of the thought processes that led to the realization our Universe is expanding.
 
  • #3
Grogs said:
Here's a thought experiment for you. If the size of the Universe is unchanging, why aren't there as many galazies moving towards us as away from us?

What about the possibility that gravity becomes repulsive
at large distances in that case (by the way this assumption has been used to solve the dark energy problem also) because there will be more galaxies at large distances so obviously there will be more galaxies going away from us.
 
  • #4
cosmoboy said:
What about the possibility that gravity becomes repulsive
at large distances in that case (by the way this assumption has been used to solve the dark energy problem also) because there will be more galaxies at large distances so obviously there will be more galaxies going away from us.
You're thinking in terms of expansion due to a force of one galaxy on another, and that the speed of recession is speed through fixed background of space. But that would make galaxies be moving faster than light through space. Try thinking as though galaxies are still with respect to their local space environment and that space itself is expanding.
 
  • #5
Mike2 said:
You're thinking in terms of expansion due to a force of one galaxy on another, and that the speed of recession is speed through fixed background of space. But that would make galaxies be moving faster than light through space.

This is what I have also said. I am looking for some
other arguments which can prove that it is actaully the
space which is expanding.
 
  • #6
cosmoboy said:
This is what I have also said. I am looking for some
other arguments which can prove that it is actaully the
space which is expanding.

I don't think you'll find any. I see the necessity of 'stretching space' as coming from a certain choice of coordinates within general relativity, rather than being a physical effect. See http://www.chronon.org/Articles/stretchyspace.html
 
  • #7
cosmoboy said:
This is what I have also said. I am looking for some
other arguments which can prove that it is actaully the
space which is expanding.
As Chronon said, you're not going to find any - at least none that are logical. Einstein believed in a static universe and he invented the cosmological constant to keep this steady-state universe stable. Edwin Hubble demonstrated that light from distant objects was redshifted in amounts roughly proportional to their distances. Hubble also believed that we live in a steady-state universe. Others looked at the redshift and said it was evidence of a Doppler-like effect, and that proved that the universe is expanding. There were some problems with this idea: Causally-disconnected parts of the universe (think of distant things on opposite sides of the sky) seemed to be very similar, with similar distributions and energies. To explain this, cosmologists invented inflation, in which every part of the universe was once in causal contact and then flew apart much faster than the speed of light. Another problem cropped up. If you interpret redshifts as recession velocities and extrapolate back to where everything must have been together (the Big Bang we all know and love :yuck: ) the universe is much too young to contain the very old objects we see around us. Cosmologists "solved" this quandry by inventing a cosmological acceleration, explaining that even though redshifts prove that the universe is expanding too fast, the Big Bang is still safe, because the universe was expanding much more slowly in the past, so there is plenty of time to accommodate the very old things we see. There is no explanation for where the energy to fuel this acceleration is coming from.

Speaking of very old things: Right now, we know of 3 (perhaps more) quasars residing at redshift z~6.5. If redshift is strictly a function of cosmological recession, these powerhouses must have masses of several billion suns, and they must reside in galaxies massing around a trillion suns each. They also have metal contents equal to or higher than our own sun AND they existed this way over 13 billion years ago, when the BB universe was only a few hundred million years old. None of this seems to bother BB cosmologists, although it should bother anybody who takes a few minutes to think about it. Some really big questions are still out there to be addressed.
 
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  • #8
Dear frinends,
this all discussion is going fine. Let me mention that
why I am worrying about this question.

"Actually I have been thinking for last few years that is
is there any meaning of space and time other than the
space is what matter needs for existence and time is
what we can say has passed after comparing initial
and final appearence of a physical system."

I think in this context you can distinguish the expasnion
of space from the recession of galaxies only when you can
define space independent from physical matter. This argument goes with time also. You can read about it here

http://www.geocities.com/vichitravira/time.html
 
  • #9
turbo-1 said:
Speaking of very old things: Right now, we know of 3 (perhaps more) quasars residing at redshift z~6.5. If redshift is strictly a function of cosmological recession, these powerhouses must have masses of several billion suns, and they must reside in galaxies massing around a trillion suns each. They also have metal contents equal to or higher than our own sun AND they existed this way over 13 billion years ago, when the BB universe was only a few hundred million years old. None of this seems to bother BB cosmologists, although it should bother anybody who takes a few minutes to think about it. Some really big questions are still out there to be addressed.
if these quasars are so massive, then wouldn't there be an addition redshift due to the great gravitational well that photons have to climb out of? Wouldn't this redshift be in addition to the redshift of recession?
 
  • #10
Mike2 said:
if these quasars are so massive, then wouldn't there be an addition redshift due to the great gravitational well that photons have to climb out of? Wouldn't this redshift be in addition to the redshift of recession?
Bingo!

Arp, the Burbidges, et al argue that quasars are black holes that are ejected from galaxies, and that they evolve with time. How can quasars possibly evolve? If you model a BH that is almost naked being shot out into the interstellar medium via radiation recoil or a multi-body slingshot effect, it initially will have an accretion zone that is very tiny, and light generated by matter infall will have to come to us from very close to its event horizon. As you know, at or below the event horizon, the light cannot escape and it has infinite redshift, and light emitted from close to the EH will be highly redshifted, proportional to the proximity to the EH. This is what a quasar looks like to us. As the black hole accretes matter from the IGM, its accretion zone grows larger, and the visible light that we see will be less and less redshifted. Eventually, the BH can accrete enough material to trigger star formation and then it will appear to us to be an AGN. If this model is correct, high-redshift quasars have intrinsic redshift that is in addition to the cosmological Hubble effect. This way, they do not have to be the most massive luminous monsters in the universe, and they won't pose the problems for standard cosmology that they currently do.
 
  • #11
What is IGM and AGN? Thanks.


turbo-1 said:
Bingo!

Arp, the Burbidges, et al argue that quasars are black holes that are ejected from galaxies, and that they evolve with time. How can quasars possibly evolve? If you model a BH that is almost naked being shot out into the interstellar medium via radiation recoil or a multi-body slingshot effect, it initially will have an accretion zone that is very tiny, and light generated by matter infall will have to come to us from very close to its event horizon. As you know, at or below the event horizon, the light cannot escape and it has infinite redshift, and light emitted from close to the EH will be highly redshifted, proportional to the proximity to the EH. This is what a quasar looks like to us. As the black hole accretes matter from the IGM, its accretion zone grows larger, and the visible light that we see will be less and less redshifted. Eventually, the BH can accrete enough material to trigger star formation and then it will appear to us to be an AGN. If this model is correct, high-redshift quasars have intrinsic redshift that is in addition to the cosmological Hubble effect. This way, they do not have to be the most massive luminous monsters in the universe, and they won't pose the problems for standard cosmology that they currently do.
 
  • #12
Mike2 said:
What is IGM and AGN? Thanks.

Intergalactic medium (gas outside of clusters and galaxies) and active galactic nuclei (including quasars and Seyfert galaxies).
 
  • #13
cosmoboy said:
Dear frinends,
this all discussion is going fine. Let me mention that
why I am worrying about this question.

"Actually I have been thinking for last few years that is
is there any meaning of space and time other than the
space is what matter needs for existence and time is
what we can say has passed after comparing initial
and final appearence of a physical system."

I think in this context you can distinguish the expasnion
of space from the recession of galaxies only when you can
define space independent from physical matter. This argument goes with time also. You can read about it here

http://www.geocities.com/vichitravira/time.html

cosmoboy's page said:
Special theory of relativity is founded on the posulate that the speed of light is a universal constant. We know that light is always related to some physical process so the time which we encounter in special theory of relativity is the physical time. However, if we take the speed of light zero or infinity then only we can define a time independent from physical process, but in that case special theory of relativity no longer remain valid. There has been proposals of imaginary time also but I think there does no exist any such time, however, one can always some parameter that can behave like imaginary time.
Time is a puzzle, and trying to divorce our definition of time from physical processes is not productive, as you noted, since that is how we experience and define time. We've also got to realize that that when we define space-time as a single construct and accept Einstein's idea that the speed of light in a vacuum is constant, we've locked time to a rigid, purely theoretical, speed of light. That can cause problems, because quantum theory tells us that "empty" vacuum is teeming with virtual particle pairs even at zero degrees Kelvin. This is the zero point energy (ZPE) field and light has to traverse this field as it crosses "empty" space. Every single field that we know can be polarized and can be densified or rarified, and this field is no different. Light has a wide range of speeds, depending on the refractive index of the material through which it is travelling, and we know from quantum physics that there is no such thing as a true vacuum in outer space. Where does that leave us? If this is true, light travels at different speeds as it travels through areas of space/time that are at different densities and/or polarities. Einstein never managed to reconcile himself with quantum physics, which is a great shame, because he had the brain-power to deal with these problems, and it probably prevented him from acheiving his ultimate goal - the unification of gravity with the other fundamental forces.
 

What is the expansion of the universe?

The expansion of the universe refers to the continuous increase in the distance between galaxies and other celestial bodies. This phenomenon was first observed by astronomer Edwin Hubble in the 1920s and has since been confirmed by various studies and experiments.

How is the expansion of the universe measured?

The expansion of the universe is measured using a variety of techniques, including the redshift of light from distant galaxies, the cosmic microwave background radiation, and the brightness of supernovae. These measurements are then used to calculate the rate of expansion, also known as the Hubble constant.

What is the evidence for the expansion of the universe?

Aside from the observations made by Edwin Hubble, there is also strong evidence for the expansion of the universe from the cosmic microwave background radiation, which shows a pattern of radiation that is consistent with an expanding universe. Additionally, the redshift of light from distant galaxies provides further evidence for the expansion.

How does the expansion of the universe relate to the Big Bang theory?

The expansion of the universe is a fundamental aspect of the Big Bang theory, which states that the universe began as a single point and has been expanding ever since. The theory also explains the observed redshift of light from distant galaxies as a result of the expansion.

Is there any debate about the expansion of the universe?

While the majority of scientists accept the expansion of the universe as a well-supported theory, there is ongoing debate and research about the exact rate of expansion and the potential role of dark energy in driving this expansion. Additionally, some alternative theories have been proposed, but they have not yet been widely accepted by the scientific community.

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