Drakkith said:I don't think that's how GR labels it. I don't have much experience with GR, but I believe the metric is just describing how space is curved, not that it moves at all. You can't have a frame relative to space, only relative to another object.
arindamsinha said:As far as faraway galaxies receding from us at c in all directions, I understand there is no "movement" of space, but "expansion" of space. It is the velocity of expansion of space that is not limited to c by GR. So perhaps this is a terminology issue.
Are galaxies really moving away from us or is space just expanding?
This depends on how you measure things, or your choice of coordinates. In one view, the spatial positions of galaxies are changing, and this causes the redshift. In another view, the galaxies are at fixed coordinates, but the distance between fixed points increases with time, and this causes the redshift. General relativity explains how to transform from one view to the other, and the observable effects like the redshift are the same in both views. Part 3 of the tutorial shows space-time diagrams for the Universe drawn in both ways.
In the absence of the cosmological constant, an object released at rest with respect to us does not then fly away from us to join the Hubble flow. Instead, it falls toward us, and then joins the Hubble flow on the other side of the sky, as discussed by Davis, Lineweaver & Webb (2003, AJP, 71, 358). In what are arguably the most reasonable coordinates, the cosmic time t and the distance D(t) measured entirely at the cosmic time t, the acceleration is given by g = -GM(r<D)/D2 where M(r<D) is the mass contained within radius D. This gives g = -(4*pi/3)*G*(rho(t)+3P(t)/c2)*D(t). The 3P/c2 term is a general relativistic correction to the otherwise Newtonian dynamics. Galaxies all move under the influence of this acceleration and their initial position and velocity. In other words, F = ma and gravity provides the force. Nothing extra or weird is needed.
http://en.wikipedia.org/wiki/Expansion_of_spaceFORTH: NO STRETCHING The surface of the balloon "stretches" and this leads to weird discussions of the "stretching" of space or the "expansion" of space. To further UN-simplify the balloon analogy, what you REALLY need to think of is the construct described in "THIRD" directly above, BUT ... take away the actual balloon material and just think of things happening to the pennies as though the balloon WAS there (so as to maintain the pennies' motion in the analogy). In other words, what cosmology REALLY says is not that space stretches or expands but rather just simply that gravitationally bound systems keep getting farther away from each other. It is DISTANCE that is changing, not space. This is another of those things that are badly served by the balloon analogy. There is of course, in some sense, "more" of something in between galactic clusters as the distance increases, but just what it is that there is "more" of gets to be a theological/philosophical discussion that gets WAY beyond the balloon analogy. I refer you to 'Metric Expansion of Space'
The metric expansion of space is the increase of the distance between two distant parts of the universe with time. It is an intrinsic expansion whereby the scale of space itself is changed. That is, a metric expansion is defined by an increase in distance between parts of the universe even without those parts "moving" anywhere. This is not the same as any usual concept of motion, or any kind of expansion of objects "outward" into other "preexisting" space, or any kind of explosion of matter which is commonly experienced on earth.
In expanding space, proper distances are dynamical quantities which change with time. An easy way to correct for this is to use comoving coordinates which remove this feature and allow for a characterization of the universe as a whole without having to characterize the physics associated with metric expansion. In comoving coordinates, the distances between all objects are fixed and the instantaneous dynamics of matter and light are determined by the normal physics of gravity and electromagnetic radiation. Any time-evolution however must be accounted for by taking into account the Hubble law expansion in the appropriate equations.
The so called 'physical' distance in cosmology doesn't have the status of invariance (independence of coordinate systems) like the line element ds^2 because the 'physical' distance is a coordinate quantity.
Locally, nothing moves faster than light. Even the most distant observers measure light at 'c' locally.
In introductory physics, "expansion", say of a heated rod, is measured relative to a practical invariant standard, say an invar. measuring tape in an instant of time.. In cosmology, "expansion", refers to something altogether more strange and unfamiliar to practical ordinary life: a change in a metric coefficient a(t) in the expression...
[In cosmology, we have to choose which 'invariant' to use as a basis for our calculations; having chosen, we can't observe them all! An implication of this is that 'increasing distances' are NOT well represented in the balloon analogy!]
Does GR even describe space as "moving"?
As I understand it yes. It is counter-intuative in the extreme but space and time are said to fall into a black hole. Likewise a spinning black hole drags time and space around with it. All of this would be nonsense unless space itself could move.,,,,Indeed if this were not part of GR then a black hole could never be black or indeed have an event horizon. ...But the photon cannot escape because although it is moving outward at c, that is only relative to space. At the EH space is moving inwards at c and so the photon stays at the EH. Further in space is moving inwards at greater than c and this drags the photon back to the singularity.
Keep in mind that there's no coordinate-independent way to define the amount of time dilation for a clock at various distances from the horizon--what we're talking about is the rate a clock is ticking relative to coordinate time, so even if that rate approaches zero in Schwarzschild coordinates which are the most common ones to use for a nonrotating black hole, in a different coordinate system like Kruskal-Szekeres coordinates it wouldn't approach zero at the horizon at all.
I believe the metric is just describing how space is curved, not that it moves at all..
The FLRW metric [distance measure] is an exact solution to the EFE but only approximates our universe because it assumes the universe is homogeneous and isotropic;
how you measure things, your choice of coordinates, the model chosen, all affect your answers. Since FLRW is the 'standard [cosmological] model', listing a few conventions within the model to illustrate its UNIQUE characteristics could be helpful: being at rest with respect to Hubble flow is what defines the universal cosmological time parameter utilized; Superluminal velocities at great distances are are result of the FLRW model metric , those FLRW distances ARE great circles and space geodesics on the balloon model especially when you think of the balloon surface as a time of radius ‘r’ [approximating a constant, fixed cosmological time, the FLRW metric starts after the initial inflationary epoch; the LCDM is a 'fine-tuned version' of the general FLRW model where the parameters are chosen to get the best possible fit to our universe, the most common distance measure, comoving distance defines the chosen connecting curve to be a curve of constant cosmological time; operationally, comoving distances cannot be directly measured by a single earth-bound observer, etc,etc.
for me space moving is the lesser of two evils. The presence of a mass does cause space around the mass to contract so that a given coordinate would move toward the mass would it not? And how can frame dragging occur without space moving? If sapce is not falling into a black hole can someone give a good description of what curved space might mean in geometric terms to put me out of my misery!
If I'm not mistaken even your favorite GR visualization of spacetime curvature is an approximation that does not fully describe the mathematics, and it reminds me of physicists admitting they don't understand quantum mechanics beyond their understanding of the math. My basic understanding of the concept of visualization in sciences in general is that if something goes beyond the 4 dimensions in the "middle-cosm" has to be understood via math or via crude approximations on those 4 (uncurved) dimensions. I've been hearing of visualizations of the type of multidimentional manifolds and the more I think of it the more it seems unfathmable and the more I suspect it's wishful thinking for full 4 dimensional understanding. In fact, some popular notions sound almost embarrassing, such as the popularized notion that extra dimensions in string theory are "small dimensions like looking at an ant on a flag pole but then zooming in on it". What does that even mean? If my vision is good I may not have to zoom into notice the extra dimensions. Notions such as that look at the end of the day non-sensical or at best crude approximations.I am not encouraged by your statement that curved space and time is not something we can visualize.
The Universal Central Observer is a theoretical concept proposed by physicists to describe a hypothetical point in space that can observe and measure the entire universe simultaneously.
This phrase refers to the concept of altering the fundamental speed of light, also known as the speed of causality. Doubling this speed would mean that information and events could travel twice as fast through space, potentially changing our understanding of the universe and the laws of physics.
At this point in time, it is not possible to double the speed of light separation. The speed of light is considered a fundamental constant in the universe, and any attempts to change it have not been successful. However, this concept is still being explored and researched by scientists.
If it were possible to double the speed of light separation, it would have a significant impact on our understanding of the universe. It could potentially change our understanding of space, time, and the laws of physics. It could also open up new possibilities for space travel and communication.
Yes, there are ongoing experiments and research being conducted in the field of physics to better understand the concept of doubling the speed of light separation. Some theories, such as string theory and loop quantum gravity, suggest the possibility of altering the speed of light. However, these theories are still being studied and have not been proven yet.