Colliding Galaxies Reveal Colossal Black Holes 134
Matt_dk writes "New observations made with the Submillimeter Array of telescopes in Hawaii suggest that black holes — thought to exist in many, if not all, galaxies — were common even in the early Universe, when galaxies were just beginning to form. Astronomers have found two very different galaxies in the distant Universe, both with colossal black holes at their hearts, involved in a spectacular collision."
Apparently. . . (Score:5, Funny)
the web site has become a black hole as well.
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Re:Apparently. . . (Score:4, Insightful)
It was particularly evil to have the link in the words 'spectacular collision' :/
Re:Apparently. . . (Score:5, Funny)
I wanted pictures of the black holes. Black hole photography can be pretty tricky - None of my pictures ever seem to come out. Just can't seem to get enough exposure on the film...
Re:Apparently. . . (Score:5, Funny)
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Nah, Heat have all the exclusive photos for this collision.
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Many amateur photographers have difficulty not to letting their thumb rest on top of the lens.
Although in this case that might actually be the best place for it.
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pics or it didn't happen...
Re:Apparently. . . (Score:5, Funny)
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Would it really be fair to say they ever approached colossal?
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Would it really be fair to say they ever approached colossal?
They have to approach 'heart' first.
Re:Apparently. . . (Score:5, Informative)
http://www.stfc.ac.uk/KE/Ind/SubArrBH.aspx [stfc.ac.uk]
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And for anyone else who was fooled, when the parent says "picture" he means it.
It is not a photograph. It is a rendition of what some artist thinks it'd look like.
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"spectacular collision" with no photos = FAIL (Score:2, Funny)
Pictures please!
Or would that be considered "galaxy pron" ?
Re:"spectacular collision" with no photos = FAIL (Score:5, Funny)
Re:"spectacular collision" with no photos = FAIL (Score:5, Funny)
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Look for Xrays and you will see them.
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The article mentined glowing blackholes though!??? (Score:1)
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I knew a girl once that I would say had a glowing blackhole...it really was spectacular. OHHHHH /andrewdiceclayvoice
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thought maybe two swirling pools of stars merging together would make a good desktop wallpaper. alas....
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Cool! Yeah, I had trouble finding them at first, but then I realised I needed to click to show it at the original size.
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That's so black hole collision. That's a picture of a black cat in a barrel of oil at night... trough the eyes of a blind man!
By the way... a beautiful picture. I have it as a screen-saver when my PC is on standby.
Re:"spectacular collision" with no photos = FAIL (Score:4, Informative)
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It doesn't seem that surprising. (Score:5, Interesting)
I don't think that discovering early black holes is all that surprising given that concentrations of matter were much greater early on.
What I want to know, is how did the universe expand beyond its own swartzchild radius?
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If one considers the law that matter/energy can neither be created or destroyed, the answer would have to be that the universe is just the exit point for the blackhole preceding it. And so on. You've heard of the infinite loop? ;)
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I'm not following you at all - matter going into a black "hole" doesn't get destroyed. There's no need for it to "come out" anywhere It's not literally a "hole" - it's just an indredibly (unfathomably) dense object.
Technically the black "hole" in the center of our galaxy is still a little spherical ball of matter and energy just like any other object - it's just that the density is high enough that gravity starts to behave strangely close to it.
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Exactly.
Compress it all into a neat little ball, and at some point, that ball will go bang. Maybe a Big Bang. What do time and other dimensional characteristics look like after the event? Something like us?
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Compress it all into a neat little ball, and at some point, that ball will go bang.
Actually the evidence suggests that you if you keep compressing the ball a bang becomes very unlikely. Once matter is pile onto the singularity, about the only way it seems to come back off it through Hawking Radiation, which is more of a "Little, Slow, Trickle" than a Big Bang.
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I have always thought that this might be the case. I think that space/time is infinite. In our little corner of this infinite void, we have our "universe" of matter and energy (galaxies, dark matter, etc.). A black hole forms and creates a singularity which sucks in matter and energy. One has to ask where that stuff goes. I surmise that the singularity just punches a hole in the fabric of space/time and dumps the matter/energy into another corner of the infinite space/time, thus creating a "big bang"
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What I want to know, is how did the universe expand beyond its own swartzchild radius?
Depending on what you take the mass of the universe to be (and age too), we may not have hit it yet.
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Re:It doesn't seem that surprising. (Score:5, Interesting)
What I want to know, is how did the universe expand beyond its own swartzchild radius?
It didn't.
To compute the Schwarzschild radius [wikipedia.org] of the universe, we need to know its mass. Recent measurements suggest that the universe is flat [wikipedia.org], and so may have infinite mass. However at a minimum we can count up the mass within the observable universe [wikipedia.org]. The observable stars in the universe have a mass of ~2*10^52, but they are overwhelmed by dark matter, which brings the total mass within our observation volume to ~4*10^53 kg. So the Schwarzschild radius for the universe is:
r = (2*G*m)/(c^2) = 2*(6.7E-11 m^3kg^-1s^-2)*(4E53 kg)/(3E8 m/s)^2 = 6E26 m = 60 billion light-years.
Since the observable universe is ~46 billion light-years in radius, this means that the Schwarzschild radius of the universe is bigger than what we consider to be "the universe." In other words, we are well within the Schwarzschild radius, leading some people to describe the universe itself as a massive black hole that we are actually inside of.
The universe probably has a mass larger than what we can observe, making the radius even larger than the above estimate. If the universe truly has infinite mass, then the radius is infinite. In other words, the universe may not have a Schwarzschild radius at all.
This is also a decent description. [nasa.gov]
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Since the observable universe is ~46 billion light-years in radius, this means that the Schwarzschild radius of the universe is bigger than what we consider to be "the universe." In other words, we are well within the Schwarzschild radius, leading some people to describe the universe itself as a massive black hole that we are actually inside of.
Not according to the Wiki [wikipedia.org]...
The Schwarzschild radius (sometimes historically referred to as the gravitational radius) is a characteristic radius associated with every mass. It is the radius for a given mass where, if that mass could be compressed to fit within that radius, no known force or degeneracy pressure could stop it from continuing to collapse into a gravitational singularity.
If the universe is smaller than its Schwarzschild radius, it should collapse into a singularity. It hasn't, so it apparently isn't.
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The universe is supposedly expanding, not collapsing.
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The universe is supposedly expanding, not collapsing.
What if you view it from the perspective of how objects would appear to have a redshift, if they were all accelerating toward a central point.
Take a massive gravitational force: A
Objects B, C, and D are arranged in a line extending from Object A. A to B is the same distance from B to C. Initially all points are at rest.
If A were something massive, B, C, and D would all appear to have a redshift relative to each other. Although they are all accelerating
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You mean like that God thing? Nah, that's a myth.
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IANAA (I Am Not An Astrophysicist) but what if there never was a Big Bang? The Universe started as a continuum of random information that just suddenly came to existence (or suddenly started to physically interact, or was suddenly transported from another universe or leaked whatever)
Ignoring the fact that there's no evidence whatsoever for that, there is in fact no reason to believe it's even within the realm of possibility. E.g. quite on par with the so-called "supernatural".
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Frankly I haven't heard a plausible explanation of "how it happened" yet... apart from "it just did". Which sounds very much like the God theory, but don't tell anyone I said that.
Re:It doesn't seem that surprising. (Score:4, Informative)
If the universe is smaller than its Schwarzschild radius, it should collapse into a singularity. It hasn't, so it apparently isn't.
As mentioned here [nasa.gov], the concept of a Schwarzschild radius is one limiting case of Einstein's equations of general relativity. It is a useful concept with various rules-of-thumb, but one must be careful in applying it to all situations. In particular, the approximation breaks down, and a full treatment using the equations of general relativity is instead necessary, for "extreme" situations (like inside a black hole, during the big bang, when applied to the entire universe, etc.).
More specifically (this site seems to explain it somewhat [ucr.edu]), the "Schwarzschild black hole" is just one solution to the equations of general relativity--it is a limiting case for nominally static matter (that is also non-rotating, spherically symmetric). Other solutions are required in other cases (e.g. the Kerr solution for rotating black holes [wikipedia.org]). The Schwarzschild solution doesn't apply to dynamic systems (e.g. rapidly expanding matter). In particular the big bang and subsequent expansion of the universe represent a different solution to the equations of GR. This solution provides for a roughly flat space but massive expansion (hence highly curved spacetime, as one would expect for such high mass-density). Our best understanding suggests that inflation [wikipedia.org] occurred (where space was expanding faster than the speed of light, although light/energy/matter/information was still constrained by c).
In my previous post I was just pointing out that the expected size for the Schwarzschild radius is very large. However that is based on a naive application of the usual rules-of-thumb. The big bang, if you will, is extreme enough that it requires a more careful treatment. Moreover, our best data right now suggests that the universe is roughly flat and infinite (and thus with infinite or at least extremely large mass), meaning that there is probably no meaningful way to apply the "Schwarzschild radius" concept to it.
Disclaimer: I'm not a cosmologist. Hopefully I didn't make a mistake.
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OK, as a former physics major (got my BS in physics and then moved on to computer science for my MS), this bugs me. The Wikipedia article you cite is interesting, but about as opaque to the non-technical reader as you can make it. And I certainly take exception to the conclusion that "flat universe = infinite mass" (which conclusion I don't think even the Wikipedia article you cited supports).
The way I always understood t
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I certainly take exception to the conclusion that "flat universe = infinite mass"
By "flat" I mean space has no curvature and is thus effectively Euclidean. This means (as far as I understand it), that space continues on forever in each direction. It doesn't wrap back upon itself and reconnect (which is what would happen for a curved geometry like spherical space). So "flat universe" = "infinite space." Now, if the matter density of the universe is roughly homogeneous on large scales (which it is within our Hubble volume), then every region of space has some mass. So "flat universe" + "h
Re:It doesn't seem that surprising. (Score:5, Interesting)
Schwarzschild radius: [wikipedia.org]
The Schwarzschild radius (sometimes historically referred to as the gravitational radius) is a characteristic radius associated with every mass. It is the radius for a given mass where, if that mass could be compressed to fit within that radius, no known force or degeneracy pressure could stop it from continuing to collapse into a gravitational singularity.
Thanks a lot... Before I was peacefully ignorant, but now you've tossed out a perfectly good question and revealed to me yet another topic for my List of Things I Know That I Don't Know...
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Thanks a lot... Before I was peacefully ignorant...
As long as you don't learn what you do not know about something "abnormal, non-Euclidean, and loathsomely redolent of spheres and dimensions apart from ours" http://en.wikipedia.org/wiki/Cthulhu [wikipedia.org], perhaps we may all remain peacefully ignorant. :)
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Man, for a moment I thought you were making a Spaceballs [imdb.com] joke, instead of a physics [wikipedia.org] reference. :-P
Cheers
What I want to know. (Score:2, Interesting)
Is how to answer my 5-year old's question of: "Ok, but whats outside the universe?"
She gets solar systems, and has a pretty good handle on galaxies and that there are lots and lots of them. I'm still trying to explain the Big Bang, and keep getting hung up on what the universe is expanding INTO.
I know, even us Big People don't have a good answer, but what the heck do you tell a kid?
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http://curious.astro.cornell.edu/question.php?number=274 [cornell.edu]
seems a good explanation to me ( the stretching sheet rubber part at least, or how things can grow apart without adding more rubber )
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Don't worry. If she hasn't gotten the big bang by the time she graduates high school, she'll almost certainly get it in college.
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please reassure your wife that i am well aware that i am a horrible person.
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Oh, I don't know... you could always let her believe in Santa Claus, the Easter Bunny, the Tooth Fairy, and God until she's old enough to decide on her own whether they're real?
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There is nothing outside the universe.
And, I don't mean emptiness. I mean nothingness.
So, the universe is expanding, but its not expanding into anything, it just is.
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Okay, err, not to be ignorant here, but where did the other black holes GO? How do they "die?"
A quick look at the wikipedia article before my boss yelled at me to get back to work was not very enlightening.
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Okay, err, not to be ignorant here, but where did the other black holes GO? How do they "die?"
A quick look at the wikipedia article before my boss yelled at me to get back to work was not very enlightening.
Black holes 'evaporate' through Hawking radiation.
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That's what I got from wikipedia too, but the section on evaporation [wikipedia.org] seemed to indicate that a black hole would have to be less than a tenth of a milimeter in diameter in order to actually evaporate, because it's taking in more energy from background radiation than it's emitting.
There didn't seem to be anything to explain how an actual sizeable black hole wouldn't just end up eating the universe.
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What I want to know, is how did the universe expand beyond its own swartzchild radius?
How do you know it did expand beyond its schwartzchild radius?
;)
Sorry, that was a little zen.
"Spectacular collision"? (Score:5, Funny)
Nothing survives.
Oh, and as the mass increases, time slows down in the vicinity. Or at least that's how it seems.
The science (Score:5, Informative)
http://arxiv.org/abs/0808.2188 [arxiv.org]
In those galaxies (Score:2)
...must be millions of inhabited worlds, each populated by beings that believed themselves to be the center of the very universe, each believing that their existence had so much significance on the cosmic scale that this would not happen to them.
Instead they find themselves in the most sucky situation in the entire galaxy...
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And I can't wait to meet them.
Highlights from TFA (Score:5, Informative)
4C60.07 - the first of the galaxies to be discovered - came to astronomers' attention because of its bright radio emission. This radio signature is one telltale sign of a quasar - a black hole, spinning rapidly, feeding on its parent galaxy. A new image captures the moment, approximately 12 billion years ago, when this galaxy ripped a stream of dusty gas from a neighbour.
"This new image reveals two galaxies where we only expected to find one," said Professor Rob Ivison ... "Remarkably, both galaxies contain super-massive black holes, each capable of powering a billion, billion, billion light bulbs. The implications are wide reaching: you can't help wondering how many other colossal black holes may be lurking unseen in the distant Universe?"
Due to the finite speed of light, we see the two galaxies as they collided in the distant past, less than 2 billion years after the Big Bang. By now the galaxies will have merged to create a football-shaped elliptical galaxy. Their black holes are likely to have merged to form a single monstrously large black hole.
"These two galaxies are fraternal twins. Both are about the size of the Milky Way, but each one is unique"
From the thats-a-lot-of-lightbulbs department?
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What really got me in tfa was the "merged black holes" so. Do black holes actually
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Remarkably, both galaxies contain super-massive black holes, each capable of powering a billion, billion, billion light bulbs. The implications are wide reaching
- yes, the implications are wide reaching. Where exactly are we going to get that many light bulbs from? We can't just let all that energy go to waste. Did anyone notice Usama bin Laden in close vicinity to the black hole? If so, can we please notify Bush?
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From the thats-a-lot-of-lightbulbs department?
Sounds more like the Eye of Harmony to me.
Yes but... (Score:2)
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Pairing a black hole with light bulbs seems contradictory to boot.
They drank too much kool-aid I'm afraid....
Not Again! (Score:1)
Layman's question (Score:3, Interesting)
I know I aught be able to work this out myself, but I'm not sure if general newtonian calculations would be accurate. Is it possible to orbit a black hole from inside the event horizon if it is big enough? It seems intuitively obvious that if you can't achieve escape velocity you shouldn't be able to reach an orbital velocity either but I thought I'd see if someone was willing to give a more solid answer.
Re:Layman's question (Score:4, Insightful)
No.
Maintaining an outward velocity = c would keep you at the event horizon indefinitely. Add a sideways component and you'd be able to orbit, but at velocity > c. Anything lower and you'd need velocity > c just to maintain height, much less to orbit.
If you could go fast enough you might be able to make a few passes in some sort of collapsing orbit, but a stable orbit would be impossible.
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Maintaining an outward velocity = c would keep you at the event horizon indefinitely.
The concept of standing still while having an enormous velocity makes my head hurt and my heart long for obedience to Newtonian physics.
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Yeah, reading it after I posted it made my head hurt too, but I still can't figure out if there's a better way of saying it... or even if it's correct... >.<
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No, it's sensible when you take into account the 'flipping' of time and space (radius) dimensions. Within an event horizon, the radius between the object and the centre of the mass becomes time-like - it can only ever increase, and doing so is pretty much inevitable. Time becomes vaguely space-like, although it's unclear if you can move in both directions along that axis, even in singularity conditions. In these conditions, the only way to move is to decrease radius (analogous to moving forward through time
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Whoops, forgot to login. ^^ was me.
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Einstein's equations predict that once an object is inside the event horizon, curvature and tidal forces necessarily strictly increase, and appear to diverge (i.e., go to infinity) in finite proper time. Physicists call this a singularity. Presumably, quantum gravitational effects dominate when things get beyond a certain threshold, but it's not clear what exactly happens then.
If a black hole is nonrotating, the smalles
Who really wrote this article? (Score:3, Funny)
ripping dusty gas? (Score:1)
billions and billions.... (Score:2)
âoeRemarkably, both galaxies contain super-massive black holes, each capable of powering a billion, billion, billion light bulbs."
Most people couldn't possibly conceive of such a number. Maybe they should tell us how many Libraries of Congress that number of bulbs could light.
Can we get a better frame of reference than that please?
chicken and the egg (Score:2)
We don't know (Score:2)
This remains one of the more interesting open questions. Did galaxies aggregate central black holes or did primeval black holes catalyse the formation of galaxies? A definitive answer would be at least worth a physics Nobel. It's also why I bothered reading this thread to the bottom.
Galactic Gamma Ray Bursters (Score:2)
When two neutron stars collide within our own galaxy, the resulting gamma burst can be a serious threat to life on Earth.
How bad would it be if two galactic black holes collided? Would they emit gamma ray bursts as colliding neutron stars do? Would the energy be released in particular directions? If suitably (and very unfavourably) directed, is there any minimum safe distance within the observable universe from such a collision?
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Colliding neutron stars was, for a long time, one of the real contenders for an explanation for GRBs (Gamma Ray Bursts), but I believe that it has faded over the last half-decade or so, as increasing numbers of GRB afterglows have been imaged, and the fine detail of the bursts have become better constrained. The leading (by far) hypothesis these days is a "hypernova" which goes directly f
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Ah, good-o! I guess I shouldn't worry about looking into the pot and finding a neutron star made of haggis, either.
[Sings a bit of Scotland's Depraved]
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You could have at least made a goatse reference. Damn it man, it was right *there*.
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Re:Very simple, actually (Score:4, Funny)
Lead on, we're right behind you.
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Feel free to go for a galactic swim, oh great enlightened one.
You should be able to get there just by jumping, since gravity holds no power over you!
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Eventually he will actually find out that black holes really do suck.
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At least the snuggle afterward.
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Well boy howdy, that would have been one unobservant ancient man to not notice driftwood, shells, crabs, and seaweed that gets washed up on the beach.
Seen any driftwood coming out of black holes?
Re:Very simple, actually (Score:4, Insightful)
I would encourage you to study what a black hole actually is, rather than trusting some random sci-fi author's unsubstantiated notion that the layman's term "hole" must mean "magical portal to another dimension".
Our present equations yield a value of "infinite" when solved for the conditions believed to exist at the center of a black hole. This is likely to only mean that our equations are buggy and need fixing.
It is not the opinion of most scientists that anything special would happen inside a black hole. If you could somehow build an infinitely resilient spaceship that could somehow shield you from the effects of extreme gravity, and assuming we are wrong about the speed of light, and that you could possibly go faster than it, the most you would be able to do with a black hole would be to go in and out of the event horizon unscathed, or perhaps bang into whatever form of extremely compressed matter exists at its center. We have no reason to believe otherwise - wormholes, however prevalent they may be in the realm of science fiction, are just an unlikely hypothesis in the world of real science. For them to exist, strange forms of matter with negative density would have to be discovered, and nobody but the wishful thinkers seriously believes in that.
(I am not a physicist, however, and as such I welcome factual corrections and additions to this post)
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Upon following a river to the sea, ancient man may have thought, "Look! The blue blood of the Mother Earth flows in, but nothing comes out! There is no way to escape the giant hole in our world!"
No ancient man ever thought that. See, ancient man knew what fish were.
Today, we take the same myopic and uninformed view. "Don't go into the black hole at the center of our galaxy! You'll disappear forever!"
Well modern thinking is that you wouldn't necessarily disappear forever; the energy that used to be you wou
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Hole in the sky, take me to heaven
Window in time, through it I fly
Yeah
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Black Hole Sun... Won't you come... and wash away the rain?