Le mer. 11 sept. 2024, 10:34, Alan Grayson <[email protected]> a écrit :
> > > On Wednesday, September 11, 2024 at 2:17:10 AM UTC-6 Quentin Anciaux wrote: > > > > Le mer. 11 sept. 2024, 10:08, Alan Grayson <[email protected]> a écrit : > > > > On Tuesday, September 10, 2024 at 3:50:08 PM UTC-6 Quentin Anciaux wrote: > > > > Le mar. 10 sept. 2024, 23:19, Alan Grayson <[email protected]> a écrit : > > > > On Tuesday, September 10, 2024 at 2:19:42 PM UTC-6 John Clark wrote: > > On Tue, Sep 10, 2024 at 3:57 PM Alan Grayson <[email protected]> wrote: > > > *>> Even if you ignore Dark Energy and postulate that the Hubble constant > really is constant, every object a megaparsec away (3.26 million > light-years) is moving away from us at about 70 kilometers per second. So > if you try to look at objects a sufficiently large number of megaparsec > away you will fail to find any because they are moving away from us faster > than the speed of light.* > > > >* That was in the past. At present, the universe is expanding at about > 70 km/sec.* > > > *Galaxies are receding from the Earth at 70 km/sec for EACH megaparsec > distant from Earth they are. The further from Earth they are, the faster > they are moving away from us, so if they are far enough away they will be > moving faster than the speed of light away from us. * > > *> You're assuming the universe today is infinite,* > > > *NO! I said IF the entire universe is infinite today then it was always > infinite, and IF it was finite 10^-35 seconds after the Big Bang then it's > still finite today. I also said nobody knows if the entire universe is > infinite or finite. * > > > *>* *Hubble's law applies to the past, not to the future,* > > > *What the hell?! * > > > *How about an intelligent reply? Obviously, if the universe is infinite > today, it was always infinite. But that's what I am questioning. For > galaxies to fall out of view, they have to moving at greater than c. Now > they aren't receding that fast. How will they start moving that fast? > You're applying Hubble's law without thinking what it says. Just because a > galaxy is now receding at less than c, how will continued expansion > increase that speed to greater than c? AG * > > > The farther they are the faster they are receding from you, so as they > continue to get farther away they receed faster from you till the point > they receed faster than c and go out of your horizon. > > Quentin > > > Prove it, if you can. I see the separation distance increasing linearly as > the radius of the sphere expands, so light can reach either galaxy, from > either galaxy. AG > > > To address your point about the linear increase in distance, here's how > distant galaxies can still recede faster than the speed of light, even with > constant expansion: > > 1. Hubble’s Law: > Hubble’s Law shows that the recession velocity (v) of a galaxy depends on > its distance (d) from us: > v = H0 * d > Where H0 is the expansion rate. This means that as the distance increases, > the recession velocity increases proportionally. > > > *But that's because Hubble is looking backward in time, when recessional > velocity was much greater than today, but slowing down after Inflation. AG* > > > 2. Linear increase in distance: > You're right that, with a constant expansion rate, the distance between > two galaxies increases linearly with time. However, because recession > velocity depends on distance, the farther apart two galaxies are, the > faster they recede from each other. So, even if the distance grows > linearly, the recession velocity grows proportionally with distance. > > > *Again, that's your conclusion using Hubble's law, when looking backward > in time. If separated galaxies on a sphere are separated at a rate greater > than c, you should be able to prove it mathematically, based on geometry, > without relying on Hubble's law. AG* > Imagine the universe like a balloon that you’re inflating. If you mark two points close to each other on the balloon and start inflating it, those two points will move apart slowly. However, if you mark two points farther apart, they will move away from each other much more quickly as the balloon expands. In the same way, in the universe, the farther away a galaxy is, the more space there is between us and that galaxy. Since each portion of space is expanding, more distant galaxies experience the cumulative effect of the expansion over several portions of space. This means that for a galaxy at a great distance, the total expansion of space is larger, which results in a higher recession velocity. > > 3. Hubble Distance: > The key point is the Hubble distance: > d_H = c / H0 > At distances greater than this, the recession velocity exceeds the speed > of light (c). This doesn't violate relativity, as it's the space between > galaxies that expands faster than c, not the galaxies moving through space. > > > *Looking backward in time, you get a result which follows from an > initially HUGE expansion greater than c, and then a slowing down due to > gravity. But using Hubble's law leads to a questionable result going > forward IMO. AG * > > > 4. Analogy of the balloon: > Think of two points on the surface of an inflating balloon. As the balloon > expands at a constant rate, the distance between the points increases > linearly. However, if the points are far enough apart, they will move away > from each other faster than a closer pair of points. Similarly, in the > universe, even though the expansion rate is constant, galaxies farther > apart recede faster due to their increasing distance. > > > 5. Why light can’t reach us: > For galaxies beyond the Hubble distance, the space between us expands > faster than light, meaning their light can never reach us. This is why > galaxies eventually move out of our observable universe. > > In summary, even with a linear increase in distance due to constant > expansion, the recession velocity increases with distance, and for > sufficiently distant galaxies, this velocity eventually exceeds c. > > * John* K Clark See what's on my new list at Extropolis > <https://groups.google.com/g/extropolis> > > hwt > > > -- > You received this message because you are subscribed to the Google Groups > "Everything List" group. > To unsubscribe from this group and stop receiving emails from it, send an > email to [email protected]. > > To view this discussion on the web visit > https://groups.google.com/d/msgid/everything-list/5485c7a2-a527-448a-b337-3c8c60466d73n%40googlegroups.com > <https://groups.google.com/d/msgid/everything-list/5485c7a2-a527-448a-b337-3c8c60466d73n%40googlegroups.com?utm_medium=email&utm_source=footer> > . > > -- > You received this message because you are subscribed to the Google Groups > "Everything List" group. > To unsubscribe from this group and stop receiving emails from it, send an > email to [email protected]. > > To view this discussion on the web visit > https://groups.google.com/d/msgid/everything-list/829f73fd-cd48-41d2-813a-18c576f447a4n%40googlegroups.com > <https://groups.google.com/d/msgid/everything-list/829f73fd-cd48-41d2-813a-18c576f447a4n%40googlegroups.com?utm_medium=email&utm_source=footer> > . > > -- > You received this message because you are subscribed to the Google Groups > "Everything List" group. > To unsubscribe from this group and stop receiving emails from it, send an > email to [email protected]. > To view this discussion on the web visit > https://groups.google.com/d/msgid/everything-list/0c1b25ca-63be-428e-bace-9b669d5933a7n%40googlegroups.com > <https://groups.google.com/d/msgid/everything-list/0c1b25ca-63be-428e-bace-9b669d5933a7n%40googlegroups.com?utm_medium=email&utm_source=footer> > . > -- You received this message because you are subscribed to the Google Groups "Everything List" group. 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