How you picture the expansion of space.

In summary, the conversation discusses various analogies for the expansion of space, including an explosion from a central point, a balloon being inflated, a graph paper with squares getting bigger, and an expanding loaf of bread dough. There is also a mention of visualizing the expansion through field lines. The conversation also touches on the idea of the Universe being infinite and the concept of an underlying structure to space. There is a brief mention of infinities in nature and the potential incorporation of Mach's Principle into General Relativity.

Which is closest to how you picture expanding space?

  • As an explosion from a central point?

    Votes: 5 35.7%
  • As the surface of a swelling balloon?

    Votes: 3 21.4%
  • Infinite flat sheet of graph paper, with squares growing in size?

    Votes: 4 28.6%
  • Infinite loaf of bread-dough growing by yeast action?

    Votes: 2 14.3%
  • Humongous donut...

    Votes: 0 0.0%

  • Total voters
    14
  • #1
marcus
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Which of these comes closest to how you picture the expansion of space?

As an explosion from a central point with galaxies flying away from the center of the explosion?

As the 3D analog of the surface of a balloon?

As the 3D analog of an infinite flat sheet of graph paper on which the squares are gradually getting bigger? (suggested by PF poster jcsd recently)

As an infinite loaf of bread-dough expanding by the action of yeast

As a humongous inflatable donut
 
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  • #2
I find it easier to imagine geometric things like that in terms of field lines. Instead of picturing an expanding area or volume, it is much easier to visualize 3 sets of lines forming a grid. Expansion then is easy to picture, with the space in between the grid squares getting bigger.
 
  • #3
Originally posted by Eh
I find it easier to imagine geometric things like that in terms of field lines. Instead of picturing an expanding area or volume, it is much easier to visualize 3 sets of lines forming a grid. Expansion then is easy to picture, with the space in between the grid squares getting bigger.

I imagine what you are describing as an infinite cubical lattice, correct me if I have misunderstood.
It seems like a good clear image and could also be seen as the 3D analog of the graph paper image suggested by jcsd.

So, to test your picture out, the CMB is believed to date from z = 1000 (estimated 300 thousand years after expansion started). So for you, space at that time would be the same infinite cubical latticework picture, but with the lines 1000 times closer together. Right?
 
  • #4
i think of it as an orb of high frequency vibations expanding, as it does so the wave lenghs get longer and more diverse up to time x
when expansion continues but the wave forms stabilize
but i also think it is expanding into a pre exsisting PROTO space
"wording not very good".
 
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  • #5
I like the ole "Balloon-A-Verse" as a 2-d spatial analogy of what is happening to 3-d spatial space, because it shows that the Universe does not have to be infinite. I hate infinities .. they are repugnant to me .. I know of nothing within the Universe that is actually infinite (i.e., it is only a mental concept), so I dismiss the idea that the Universe might be infinite.

And, in trying to return that back to a 3-d spatial view of the Universe expanding, I like to think of it somewhat like a sponge, the fibrousness (is that a word??) throughout the sponge representing a fabric of space. It shows an underlying structure that I believe the Universe has.

For expansion, imagine pulling apart the sponge from all sides, but as the volume increases, I think of the fibrousness not getting diluted any, or getting pulled apart. Actually, the fibrousness stays constant, because as the Universe is getting pulled apart, new fibrousness is constantly getting created to fill in the gaps. I think that corresponds to what we think of as the false vacumn, and energy, and furthermore that energy being viewed (later) as matter, by some unknown process.

So, the Universe didn't create all of its matter/energy at the BB .. it was just the most concentrated episode of matter/energy creation. It is continually being created, as a consequence of expansion.
 
  • #6
proto space is akin to but not, a mixture of two gasses that have the property of stabillity ,a deficiency of one of the gasses would allow the other gass to erupt "similar to exposing phosphorus", the eruption would be our universe, as proto space wants to be stable the eruption would disperse to infinity.
"terrible analogy because the gasses don't exsist" but the two THINGS do. must get back to the institute bye.
 
  • #7
Originally posted by marcus
I imagine what you are describing as an infinite cubical lattice, correct me if I have misunderstood.
It seems like a good clear image and could also be seen as the 3D analog of the graph paper image suggested by jcsd.

So, to test your picture out, the CMB is believed to date from z = 1000 (estimated 300 thousand years after expansion started). So for you, space at that time would be the same infinite cubical latticework picture, but with the lines 1000 times closer together. Right?

Something like that, though the lines don't have to be that much further/closer. The distance between lines in a graph can represent any arbitrary distance you want, so in the early universe the scale becomes much smaller.
 
  • #8
As for infinities showing up in nature, I'm not so sure it's easy to brush away. How about the infinity of points, lines and planes in any given volume? Even if space is actually a discrete lattice, is it not true those lines would still be a continuum of points? Other infinities show up in nature as well.
 
  • #9
BTW, I like the ole "Balloon-A-Verse" analogy for another reason. It shows (to me at least) that both Einstein and Newton were correct. I know I'm treading on thin ice here! Be kind!

Einstein is correct because (as I understand GR with my limited knowledge of it) GR is a description of what can be or could be observed in the Universe using things contained only in that Universe. I think it fails to fully answer what mass/inertia is. I mean, I think there are two components of inertia: a component gained by motion within the Universe, but there is also a "base" value of inertia, or call it mass, that GR doesn't account for. Another way to state it is that not all concepts of Mach's Principle (not that I believe MP) are incorporated into GR. I've read where some cosmologists agree that MP can be fully incorporated into GR if the Universe is finite and unbounded.

Newton is correct too as there is absolute motion. Back to the "Balloon-A-Verse". The surface is used to show that no point on the surface is the center of expansion, and since no point is the center, that all motion has to be relative. But, acceleration and rotation are not relative. But looking at the balloon, there is a center of expansion, or a place to measure things from absolutely .. the center of the balloon. Einstein's GR doesn't consider it as it considers stuff only within the 3 spatial dimensions. This center lays outside of what we are able to reference with our senses, or observation.

And therein also is the description of that "base" mass/inertia that GR cannot describe fully. It is actually caused by motion, or acceleration maybe, through a 4th spatial dimension .. moving away from that point/center of expansion. Expansion itself is the cause of the base inertia. We're not just "hanging" in 4-d spatial space reference, but moving/accelerating through it. GR only comes about as a correct description because it doesn't consider that "base" mass/inertia/motion.

And, I think if you're careful, the problems of understanding rotating objects, why they tend to remain rotating on the same axis for one, drops out too. I can't fully invision this, but rotation is absolute to that point of expansion in the 4th spatial dimension, i.e., any way you could orient yourself in 3-d space and rotate still constitutes rotation around that point in the 4th spatial dimension.
 
  • #10
As for infinities showing up in nature, I'm not so sure it's easy to brush away. How about the infinity of points, lines and planes in any given volume? Even if space is actually a discrete lattice, is it not true those lines would still be a continuum of points? Other infinities show up in nature as well.

I'm not sure that is so much of a "physical" attribute of nature/the Universe, but a mental constraint imposed on the Universe by our need to try to describe it. I don't think it a clear-cut case of an infinity in nature.

What other infinities do you say show up in nature?
 
  • #11
I'm not sure that is so much of a "physical" attribute of nature/the Universe, but a mental constraint imposed on the Universe by our need to try to describe it. I don't think it a clear-cut case of an infinity in nature.

Well, we can logically show that points exist in any given volume. So in that sense, they are real in that they exist, and there are an infinite number of them.

What other infinities do you say show up in nature?

Let's say, the charge of an electron as you get closer and closer to it. That kind of infinity that seems to show up often. As well, there is the wave function in quantum physics that give us an infinite amount of possible states for the universe as a whole. Unless one can throw away wave functions as not being real, that would seem to be another unavoidable infinity.
 
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  • #12
Well, we can logically deduct points from any volume. So in that sense, they are real in that they exist, and there are an infinite number of them.

Well, for this, and back to your original point that a volume can be representated by an infinity of points, lines, etc. I think that is akin to the argument/paradox that goes like this:

Given a distance to cross, you can never reach it because you first have to go 1/2 the distance, then 1/2 of what is remaining, then 1/2 of what is remaining, etc. You should never reach it, but clearly you can and do reach that distance. It's an infinity argument, and the problem I see with it is that it supposes that time and/or space can be infinitely subdivided, and that the infinity holds only as a concept, not in the nature of distances.

Let's say, the charge of an electron as you get closer and closer to it. That kind of infinity that seems to show up often. As well, there is the wave function in quantum physics that give us an infinite amount of possible states for the universe as a whole. Unless one can throw away wave functions as not being real, that would seem to be another unavoidable infinity.

In the end, I think that is basically the same "1/2" argument as above, as the measure of the charge of an electron by other methods does yield a finite value. It's only our trying to calculate the charge of that electron, using QED, that introduces the infinities, and indication of a failure of QED; it not being a complete description.

A problem with my arguments here is that all we know or can know about the Universe comes from our thought processes. I'm defining "infinity" to originate in and exist only because of our thought processes. I can always fall back on that in denying infinities! ;) But I don't think our thought processes are/should be considered as being separate from the Universe. In that respect, there is a case of infinity in Nature.

I'm getting philosophical there, but I don't think it can be completely removed from most scientific discussions.
 
  • #13
I'm really glad you brought a
selection of baked goods. I'll
have a doughnut please. I don't
see any reason to rule out a
great roiling, expanding toroid,
such as you see at the base of
nuclear blasts.
 
  • #14
Originally posted by zoobyshoe
I'm really glad you brought a
selection of baked goods. I'll
have a doughnut please. I don't
see any reason to rule out a
great roiling, expanding toroid,
such as you see at the base of
nuclear blasts.

effective use of alliteration and
assonant dipthongs---roiling toroid
good image with a good sound
personally I greatly prefer raisin bread to donuts
 
  • #15
Absolutely. You are a physicist
and a gentleman. And a convivial
thread host.
 
  • #16
Originally posted by Nacho
Well, for this, and back to your original point that a volume can be representated by an infinity of points, lines, etc. I think that is akin to the argument/paradox that goes like this:

Given a distance to cross, you can never reach it because you first have to go 1/2 the distance, then 1/2 of what is remaining, then 1/2 of what is remaining, etc. You should never reach it, but clearly you can and do reach that distance. It's an infinity argument, and the problem I see with it is that it supposes that time and/or space can be infinitely subdivided, and that the infinity holds only as a concept, not in the nature of distances.


Yes, it's called Zeno's paradox. It doesn't seem to hold as much water these days. There have been several threads on this on this site, and one is at https://www.physicsforums.com/showthread.php?s=&threadid=3848&highlight=zeno from the math forum, and one from the philosophy forum at https://www.physicsforums.com/showthread.php?s=&threadid=1589&highlight=zeno

In the end, I think that is basically the same "1/2" argument as above, as the measure of the charge of an electron by other methods does yield a finite value. It's only our trying to calculate the charge of that electron, using QED, that introduces the infinities, and indication of a failure of QED; it not being a complete description.

Yes, those seem to arrive with the assumption on continuous space. But even if it is discrete, the same problems with the lines arise, and the infinities of wave functions seem to be intact.
 
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  • #17
Yes, those seem to arrive with the assumption on continuous space. But even if it is discrete, the same problems with the lines arise, and the infinities of wave functions seem to be intact.

Hmmmm. I could say that there would be infinities in a wave function only in an infinite Universe, but if I did that would make my whole argument chicken-and-egg (i.e., one reason I say the Universe is finite is I know of no infinities in it, and then the reason this couldn't be a "real" infinity is because I believe the Universe to be finite). So, I'll look elsewhere ...

I think you (meaning anybody) have to look to the collapse of the wavefunction for the answer. The wave function is predictive up until that point, and only gives you probabilities. Can you assign a "true" (using that term loosely) meaning to the wave function or its collapse? I'm under the belief "no", to either. But, then again, the Universe to our knowledge seems to act out only under possibilities.

Also, doesn't the wave function deal with "things" that are to be detected? I mean, it doesn't predict nothing will happen, does it -- or it doesn't ever have give an amplitude of zero does it? If it doesn't ever give an amplitude of zero, I don't see how it could represent infinite possibility (probability is 1/amplitude?, or something like that).

I'd say you had a "possible" infinity there. I'm not sold yet! ;)
 
  • #18
Ω0 = 1.02 ±0.02

In the course of watching cosmologists I have gradually become more interested in knowing their current consensus view than in having an opinion myself!

What they often say in words is that the U is spatially flat. The most natural picture to go with that is what Eh said:

an expanding 3D grid made of 3 sets of parallel lines
like infinite 3D graph paper, it starts out infinite and it continues that way but with the lines getting farther apart.

but I was just looking at the best current summary of cosmology
which I believe is the Lineweaver article and it said, as so many other articles do,

Ω0 = 1.02 ±0.02

that is there is an ERROR BAR
and just think, if Ω0 = 1.02 then NACHO IS RIGHT and the whole thing does after all look like a 3D EXPANDING BALLOON.

Ye gods. In that error bar there is room both for the perfectly flat infinite space of Eh with
Ω0 = 1 (exactly)
and the positively curved finite space of Nacho with
Ω0 = 1.02

The case with Omega > 1 used to be called the "closed" case but that open/closed terminology has become confusing with the discovery of dark energy. They would ordinarily assume a zero cosmol. const. Λ and then Omega > 1 finite was always doomed to collapse in a Big Crunch wherease Omega = 1 flat was able to expand indefinitely. But now with a positive Λ even the balloon model can keep expanding forever.

Indeed the indications are that this one we are in, whether Omega is 1.00 or 1.02, will expand increasingly rapidly forever.

Anyway either picture is reasonable because of the error bar and Ned Wright in his most recent "News of the Universe" has a page where he is considering the finite universe Ω = 1.02 case and fitting supernova data to it to see how it looks. He is obviously keeping an open mind. As behooves him as a scientist because if there is an error bar then it could turn out either way.

What is this Omega-sub-naught?
It is the present value of the average density of energy in the universe divided by the critical density. the zero subscript means present value since both the real density and the critical density are changing.

Ω0 = rho0/rhocrit

The best list of the current specs, with error bars, occurs in several places one of which is Lineweaver page 32

http://arxiv.org/astro-ph/0305179 [Broken]

But he is just copying the WMAP report of Bennet et al

http://arxiv.org/astro-ph/0302207 [Broken]

and the WMAP satellite is sitting out there a million miles from Earth in its own orbit around the sun and telling us what Omega and other stuff is and until they fly a more accurate instrument they won't be able to say whether Nacho picture or Eh picture is the right one
 
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  • #19
marcus,

Good read, even though I didn't understand much of it. Section 9 was the best. What caught my eye was Omega(tot) being 1 within measurement errors. It hovering around 1 like that is probably the worst thing that could happen for telling us whether the Universe will expand forever or not. Their error bar may get better in time, but I doubt they will ever be able to tells us which it is: 1 side or the other 1, or 1 exactly. That is, with these kind of measurements.

Theory is going to have to take over, and make its best case for which one it is. I think the Inflationary theory seems to indicate (by reasoning) that it is exactly 1, as inflation would have stretched it out if it was not exactly 1. That is one reason I say their measurement errors may get better, but they're not going to get good enough (1 part in 10^60, or around there).
 
  • #20
Originally posted by Nacho
...It hovering around 1 like that is probably the worst thing that could happen for telling us whether the Universe will expand forever or not. Their error bar may get better in time, but I doubt they will ever be able to tells us which it is: 1 side or the other 1, or 1 exactly. That is, with these kind of measurements.

Theory is going to have to take over, and make its best case for which one it is...

I agree. the error bar most likely will straddle cases around
omega = 1. it is simplest to just suppose it is exactly one
especially with the theoretical reasons for that which people have raised

the role of inflation seems likely to change if the singularity
at time zero is removed and the model predicts a prior
contracting phase, but I gather the people involved want to
keep inflation as part of the story, and merely narrow down the problems it is supposed to solve
it solves
 

1. How does the expansion of space occur?

The expansion of space occurs due to the presence of dark energy, a mysterious force that is thought to be responsible for the accelerated expansion of the universe. This dark energy causes space to stretch and expand, carrying galaxies and other objects along with it.

2. Is the expansion of space constant?

No, the expansion of space is not constant. In fact, the rate of expansion is increasing, meaning that the distance between objects in the universe is growing at an ever-increasing rate. This is due to the continuous production of dark energy, which causes space to expand at a faster and faster rate.

3. How does the expansion of space affect objects in the universe?

The expansion of space has a significant effect on objects in the universe, particularly on large scales. As space expands, it carries clusters of galaxies and other objects with it, causing them to move further apart from one another. This also affects the gravitational interactions between objects, potentially leading to changes in their orbits and other behaviors.

4. Will the expansion of space ever stop?

It is currently believed that the expansion of space will continue indefinitely, as long as dark energy continues to be produced. However, there are some theories that suggest the expansion may eventually slow down or even reverse, leading to a "big crunch" in which the universe collapses back in on itself.

5. How do we know that space is expanding?

Scientists have observed the expansion of space through various methods, such as measuring the redshift of distant galaxies and studying the cosmic microwave background radiation. These observations have provided strong evidence for the expansion of space and have helped to refine our understanding of its rate and effects on the universe.

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