Submitted by crazunggoy47 t3_11fkfeq in askscience
nivlark t1_jak3izy wrote
Locally, the expansion of the universe still obeys the first law of thermodynamics: considering a fixed proper volume of space, expansion acts to dilute the energy density within that volume, doing work in the process.
The energy to do this "comes from" the expansion, which means it slows down over time in the situation where there are attractive forces (i.e. gravity) associated with the energy density. Conversely the present-day universe has its energy density dominated by dark energy, which behaves as a repulsive force which ads energy to the expansion, accelerating it.
For a rigorous derivation of this behaviour your best bet is to get an introductory cosmology textbook and look into the Friedmann equations.
DocJanItor t1_jam805g wrote
That answer seems kinda counterintuititive to me considering that the universe is larger than the equivalent size it should be for its age and the speed of light. Thus, the expansion of the universe has obviously gone faster than light and has broken a major physical limitation of the universe itself. Why would we expect that expansion follow other in universe laws?
nivlark t1_jamd3iu wrote
Sufficiently distant objects have apparent recession velocities greater than the speed of light, but this doesn't break any physical laws. Special relativity says that velocity measured in an inertial frame will never exceed the speed of light, but cosmologically distant galaxies are not inertial from our perspective.
ableman t1_jammpqd wrote
> Special relativity says that velocity measured in an inertial frame will never exceed the speed of light, but cosmologically distant galaxies are not inertial from our perspective.
We are in an inertial reference frame, so we are measuring from an inertial reference frame, it shouldn't matter what frame they're in, SR works just fine on accelerating objects, as long as the observer is inertial. If you meant to say we're not in an inertial reference frame, it's a very poor explanation, because that's just a No True Scotsman fallacy, but also just seems wrong? The whole point of inertial reference frames is that you can tell whether you're on one or not with a local experiment.
nivlark t1_jaogkfl wrote
Our reference frame is only locally inertial, where "local" means "close enough that the global geometry of spacetime can be ignored". In special relativity spacetime is flat everywhere and there is no such distinction, but in GR the same is not generally true.
zutnoq t1_janifi1 wrote
Indeed, the inertial-ness of a reference frame is only a local property (local here meaning infinitesimal displacements).
[deleted] t1_jamkmzv wrote
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Aseyhe t1_jamocwu wrote
Repeating a response I made to a similar question elsewhere in the thread:
Relative velocities of distant objects aren't well defined in curved spacetimes. It's often said that distant objects are receding faster than light, and there are standard ways of writing down their distance such that the distance grows faster than the speed of light. However, there is no relativistically meaningful sense in which these objects are moving faster than light in relation to us. Also, the distance isn't uniquely defined either.
In intuitive terms, the relative velocity is the angle between two vectors in spacetime. Imagine drawing two arrows on a sheet. If those arrows are in the same place, you can measure the angle between them. If they are in different places, but the sheet is flat, you can also define the angle between them uniquely. However, if they are in different places and the sheet is not flat, the angle between the arrows is not uniquely defined.
[deleted] t1_jamtdac wrote
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DocJanItor t1_jan4djg wrote
Doesn't matter about their current velocities. The universe is 14B years old. It's bigger than 28B light years wide. Therefore the universe had to expand faster than the speed of light.
Further, light goes through the universe. The universe expands outside of itself into who knows what. We have no idea if the speed of light applies outside of the universe. Same for thermodynamics.
Ape_Togetha_Strong t1_jan9j7f wrote
It sounds like you're imagining "expansion" to be some outward expansion from a point in space, rather than spacetime expanding everywhere. There's no reason to tie the age of the universe to its size (other than just how its size changes proportionally, relative to itself with time). It could have been any size prior to inflation. The fact that the observable universe is larger in lightyears than the age of the universe in years is not surprising or particularly meaningful.
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Possible-Quail-7376 t1_jb1bhnu wrote
allright but the universe as we know it might be one string, layer of whatever. looking at the big picture, anything goes really. assuming the universe is same shape as the rest of stuff (toroidal) doing same stuff as atoms, quantum particles and stuff like that on what knows dimensions..
well, i guess we live in positive side of universe since stuff seems to expand. One string in a field. perhaps that is the part what scientists would call the universe part.
to be continued...
[deleted] t1_jalwfcp wrote
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Hudimir t1_jango8k wrote
What you said about dark energy acting as a repulsive source, I am now confused how so.e scientist recently came to the conlusion that black could be sources of dark energy. Especially because afaik black holes are incredibly dense objects made form "normal" matter that collapsed due to their gravity. Here dark energy being a repulsive force doesnt make sense to me if all we can observe is the incredibly powerful gravitational waves of black holes.
summitrow t1_jao6p2q wrote
Dark energy and black holes are separate. Black holes are objects that are black because their gravity well is so strong that light cannot escape them. Dark energy is a force that pervades all of spacetime. We measure how much dark energy there is by the red shift of galaxies outside of our local group, and other standard candles like class 1a supernova and Cepheid variable stars. Is there a dark energy particle? Is it a fundamental force like the strong force in an atom? We don't know. So far we can just measure its impact on the expansion of the universe.
Hudimir t1_jao97us wrote
Correct me if i misunderstood. So in that article where they say black holes might be the source of dark energy they say so, because they measured/observed more dark energy impact around those black holes? Also fyi i am currently studying undergrad physics so the very basics(e.g. black holes are black because light cannot escape them) I think, I understand, so you can complicate more if you have the knowledge.
VegaGraviton t1_jaok1al wrote
I had a brief reread of the articles discussing the theory. Bear in mind that my personal background is in Cosmic Inflation and so I'm not intimately familiar with this theory. From what I gleamed Einsteins Equations can predict an object that is essentially a concentrated bundle of Vacuum Energy, which is a commonly theorised candidate for Dark Energy. This object would look and act like a Black Hole to outside observers. Therefore, any Black Hole that we observe could in fact be a source of Dark Energy, and we wouldn't be able to tell with our current understanding of the model.
Essentially its a mathematical model that has been proposed, rather than any new observations.
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summitrow t1_japc8y4 wrote
Yes light cannot escape them, which is because of the incredibly strong gravity well of a black hole.
The very recent articles on black holes and dark energy are very speculative.
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