Can someone explain how is it possible for black holes to even collide? Wasn't the usual expanation that time goes faster (for you, slower for outside observer) as you approach the black hole singularity and that it stops exactly as you "get there"? If this is true the black holes never actually collide. They just endlessly spin closer and closer. For the outside observer it taking infinite time before they actually "touch"?
Or do we just call it a collision if they simply get as close to each other as to be within the event horizon of the other?
If the former and we see these true collisions, how is it not a proof the age of the universe is infinite ? If we see events that are supposed to take infinitely long to occur?
An observer falling into the black hole would not observe any distortion in time. They would simply fall in, under the influence of gravity. From the perspective of a far-away observer it would look as if time is slowing down as the photons would take increasingly longer to escape. At the event horizon the photons would effectively be held in place. Eventually though, the last photon will have escaped and you will just observe a slightly larger black hole.
So the merger definitely happens from the point of view of the black holes. We might observe odd artifacts but they would eventually fade away.
> From the perspective of a far-away observer it would look as if time is slowing down as the photons would take increasingly longer to escape.
Photons travel at the speed of light always, that's what Einstein told us.
So rather, the observed energy (frequency) of the photons decreases, and it takes longer between each photon.
At least that's my understanding.
Black holes' radius is linear in proportional to their mass, they are not constant density, larger ones are less dense. Therefore, when a 5 solar mass BH merges with another 5 solar mass, the radius doubles, surface area quadruples, and volume goes up 8x. If they "never actually merge", SMBHs would not exist.
They can merge event horizons on a finite timescale from the outside and still take an infinite amount of time to merge singularities or whatever it is that singularities do when they meet up in the privacy of an event horizon.
Subject to local laws and conventions, of course.
Collision is when they approach each other, then round down to one black hole.
I don't get it. There are black holes that have millions of sun masses. The current theory is that these were formed by many consecutive mergers. What then makes this 225 sun mass merger so large that it shouldn't exist?
Large mass stars are very, very few in number, and have short lifetimes, so collapse into black holes (if it happens), and then mergers are vanishingly small. 225 solar masses black holes are in the realms of unlikely if only had that information.
https://en.wikipedia.org/wiki/List_of_most_massive_stars
Then again, the universe is really big and to paraphrase Pratchett, million-to-one chances happen nine times out of ten.
https://en.wikipedia.org/wiki/Phoenix_Cluster#Supermassive_b...
"Such a high mass may place it into a proposed category of stupendously large black holes (SLABs), black holes that may have been seeded by primordial black holes with masses that may reach 100 billion M or more, larger than the upper maximum limit for at least luminous accreting black holes hosted by disc galaxies of about 50 billion M[12]"
(which comes from a paper from one of my old lecturers).
If we accept that primordial black holes do indeed exist (the evidence against, is, I believe that they should be evaporating about now, but are as yet unobserved), there must therefore be a weight distribution of those, which means there are probably other 'solar mass' 'seeded' black holes lurking, that were never created by stellar collapse.
To make a stupendously large black hole, you only need a stupendously large amount of mass in the galactic core, no need for primordial black holes. Coincidentally Phoenix galaxy is stupendously heavy.
There are no medium sized bkack holes. As far as we look back in time with james webb,the largest are already there.
Just guessing, but maybe the common situation is that one ever growing black hole absorbes small ones? But that two of these large ones merging "should not happen"?
Greg Egan's Diáspora starts with the merger of two neutron stars, and that causes a lot of trouble in this side of the galaxy, don't want to imagine what would it be with 2 massive blackholes for the nearby galaxies.
It wouldn't do anything special actually. A black hole from a distance does nothing a sun can't do.
Black holes only become destructive/powerful when you are very close to them.
To elaborate: A black hole is mass, a sun is mass. From a distance there's no difference. The only difference is up close - you can get a lot closer to a black hole dramatically increasing the gravitational force.
But from a distance? Nothing special.
Black holes can have a relativistic jet. M87 has one that extends ~5000 light years.
These jets can kill from a long distance.
Suns can also kill from a long distance.
From even a reasonable distance those jets are quite diffuse, you could pass through one and not notice.
We often imagine them as space vacuums sucking everything in, but they're really just compact mass: spooky only if you get way too close
then there are the jets the black holes may form, and I wouldn't like to pass through one
No, those jets look amazing from a distance, where you are looking at a galaxy sized object. But up close they are very thin and you probably would not notice passing through one unless you were checking carefully.
Except black holes can be a lot more massive than the biggest stars.
Which is true, but also just means you need more distance. And if there is anything in space it is distance.
Thanks for that. I guess I had always assumed that over a long enough time frame, black holes would eventually swallow everything.
In a static universe, they absolutely would.
In a shrinking univers, they absolutely would. (But neither of these things would necessarily have already happened.)
In an expanding universe, some things will eventually so far away from black holes that they won't get "eaten". Also, they won't see them anymore, nor most of the rest of the universe.
That third option is, to our best knowledge, the one we live in.
An interesting implication is that, if intelligent life evolves several billion years from now in any given galaxy, it's galaxy might be so far away from its nearest neighbors that light from them will never reach it. That civilization's Hubble will never be able to test their crazy theory that "there could be more than one galaxy in the universe".
What about the huge gravitational waves?
inconsequential for the most part, gravity doesn't interact directly with matter (which I understand, might be still quite counterintuitive to many). I do wonder though if it would be possible for the "ripple" to deorbit us (or any other body).
The waves aren't that strong, at "safe" distances. Otherwise, we'd all experience shared vertigo.
You would not notice even a strong wave.
The wave moves your entire body, and the ground, all at the same time. You would not notice anything because it all moves together.
OK, not at exactly the same time - but you need specialized equipment to detect it, AKA the machines in the article. A person would not notice even a strong wave.
We're agreeing.
It’s impressive how LIGO and Virgo keep pushing the limits of what we thought was possible. Each new event seems to open more questions than it answers.
So this article confused me.
After digging around, the masses of these Black Holes are in the forbidden zone, where there shouldn't really be Black Holes of that size because of how they are formed.
They are usually either bigger or smaller depending on their origin. They could be second or third generation Black Holes, which would be unlikely due to the probability of them forming in close neighborhood. So what their reason for existing there are questions that should lead to some interesting answers if we ever get to the bottom of it.
225 solar masses… that's just wild. We keep building these models that tell us mergers like this shouldn't happen, and the universe keeps dunking on them
The models are constrained by what is known at the time they are built - those that clash with existing observations are discarded while those that don't, get published.
The article fails to explain why this event challenges our understanding of black holes. Did we expect such big masses to spiral for much longer or something? Why was this collision supposed to stay unstable?
There just isn't a way to make black holes that big from the collapse of stars when they go supernova.
So maybe both of these black holes formed from earlier mergers of smaller black holes. Or maybe there are other ways to make larger black holes we don't know about. They are in a range of mass we don't really expect to see theoretically.
Way to headline.
The numbers in the article suggest a violation of conservation of mass:
> Today, the LIGO Collaboration announced the detection of the most colossal black hole merger known to date, the final product of which appears to be a gigantic black hole more than 225 times the mass of the Sun.
> GW231123, first observed on November 23, 2023, seems to be an unprecedented beast of a black hole merger. Two enormous black holes—137 and 103 times the mass of the Sun—managed to keep it together despite their immense combined mass
Is the explanation here "225 is a nice round number, and 240 is technically 'more than' that", or "a lot of mass evaporates into other forms of energy when black holes merge", or "during a merge, it becomes possible for matter to escape an event horizon", or what?
the extra mass is converted into energy in the form of gravitational waves (maybe other forms too idk but this is part of it)
Entire solar masses being lost to gravitational waves, like the voltage drop across a resistor, is a humbling prospect.
I'll underscore your awe by reminding you those solar masses disappeared in only 1 tenth of a second - the length of the gravitational wave signal.
but that's the time that passed here... it sounds like a mind-warpingly different perspective might have been seen there
I think you have it backwards. From the POV of someone near the Event Horizon, other space speeds up. Galaxies begin to spin at noticeable speeds.... But the black holes would appear to be approaching each other at "normal" speeds.
Dang
I suppose nothing but gravitational waves can escape the even horizon — or, rather, gravitational waves are born near / around it, because the black holes bend the space enormously.
OTOH whatever else may be outside the black holes near the merger and count towards their mass for astronomical purposes, such as accretion discs, should be much lighter weight than what's inside the event horizon.
Gravitational waves also can not escape. Those waves carry energy, and it's actually energy that can't escape.
The waves are actually made just to the outside of the event horizon.
I always understood that the waves are "made" everywhere, but that only the waves outside the even horizon will escape.
Was my understanding wrong all along?
Sort of correct?
Time is halted inside the black hole, so the waves made inside it never show up. Static gravity does show up though, but changes do not.
> The waves are actually made just to the outside of the event horizon.
How do we feel about this vis-a-vis action-at-a-distance?
Gravity does action at a distance. That's its thing.
The reason these waves are not generated from inside the black hole is that, to us, time stops there. For example these black hole mergers aren't actually merging, they are getting closer, and then they time dilate out of existence.
> Gravity does action at a distance. That's its thing.
Why does it need to travel in waves at the speed of light? If one mass moves, a distant mass is unaffected until the information reaches it. That's the opposite of action at a distance.
Your question is confusing. Action at a distance does not imply going faster than light, it means there is some sort of field connecting the two things.
Action at a distance means there is nothing connecting the two things. That's the "distance" part of action at a distance. Modern physics rejects the concept, saying instead that forces are carried by particles from a source to a destination, and the effect of the force is the result of local [opposite of "distant"] interaction with the particles carrying the force.
Compare wikipedia:
> Under our modern understanding, the four fundamental interactions (gravity, electromagnetism, the strong interaction and the weak interaction) in all of physics are not described by action at a distance.
( https://en.wikipedia.org/wiki/Action_at_a_distance )
Or: https://en.wikipedia.org/wiki/Principle_of_locality
> This is an alternative to the concept of instantaneous, or "non-local" action at a distance.
> The idea is that for a cause at one point to have an effect at another point, something in the space between those points must mediate the action. To exert an influence, something, such as a wave or particle, must travel through the space between the two points, carrying the influence.
You'll note that "action at a distance" does in fact specifically mean that information travels faster than light!
But this understanding would seem to be incompatible with the idea that the mass inside a black hole can interact gravitationally with anything outside the black hole.
I'm not seeing where any of this requires faster than light travel.
But here's something that might help: We'll use gravity for our example, and I'll be non-technical for ease of typing.
The gravitational force that leaves an object is constant and continuous, it never stops, and it never starts. It exists from before the beginning of time, and it will never stop. The only thing you can do with that force is move it. This is because it's impossible to destroy energy. If you move the mass (the energy actually if you want to be exact) then you have changed the location (but not the strength) of the gravitational force, and that CHANGE travels at the speed of light.
So the gravitational attraction of my hand has, right now, already reached the end of universe, out to infinity. When I move my hand, it sends a tiny gravitational wave that travels at the speed of light, indicating a change in where the force is.
So the gravity inside the black hole has already reached the end of the universe, when that matter starts to clump, a change in the location of the gravity is sent out saying "this gravity is now moving over here".
This is why it feels like it's moving faster than light - it's not, it's already there at the end of the universe.
This is also why the orbit of Mercury is different in relativity, the sun pulls on Mercury where it WAS in the orbit, not where it is (which would require faster than light travel). In Newtonian gravity it's instant (i.e. faster than light).
What's going on here?
What part of your comment says something about gravity that is different from what I've already said about it?
How do you look at a quote stating explicitly that action at a distance is, by definition, instantaneous, and say "I'm not seeing where any of this requires faster than light travel"?
> So the gravitational attraction of my hand has, right now, already reached the end of universe, out to infinity.
And how has the gravitational attraction of your hand gone more than 200 light years from Earth?
Rather confused. 225 solar masses isn’t gigantic by any means
it's above what's considered possible to create by usual star collapse means
https://en.wikipedia.org/wiki/List_of_most_massive_stars lists only 2 stars more massive than that
So if you have two black holes within each other's event horizons, but they're too big to collide, what's supposed to happen instead?
Nothing is too big to collide, the issue here are the initial masses which are bigger than expected from core-collapse stars
The situation you describe is impossible. "If you have a very large positive number that is less than zero, what happens?"
I have read elsewhere that all black holes are imploding, and there will be a "bounce" followed by matter emerging from the event horizons.
https://www.popularmechanics.com/space/deep-space/a65038572/...
GR doesn't say any such thing, and anything beyond GR is speculation.
What's the contradiction in the black hole setup?
If one is within the other's event horizon, they have already collided (and are now surrounded by a common event horizon).
I'm not even sure what it would mean for two black holes to be too big to collide, or where that became some kind of constraint.
I thought it was just thought that it would take too long for them to spiral into each other for it to have happened enough times in our universe
You're imagining some moment where two points merge.
These aren't points; they are (literally) opaque volumes of space, and once their outer limits broach, they have collided.
By analogy, two warships can collide, even though their centers of mass don't.
It would be difficult for two warships to collide without some of the material in one warship touching some of the material in the other one.
But there is no matter at an event horizon. That's just an imaginary line in space. It's opaque, but not solid.
If the black holes were moving fast enough, it should be possible for their event horizons to cross and then uncross, although that would immediately raise the question of what would happen to matter in the zone of overlap. Perhaps "fast enough" would exceed the speed of light?
I think you're playing fast-and-loose with the notion of "colliding".
First define what you mean by "colliding".
By analogy, I'm defining it as the Event Horizons intersecting, at which point nothing in side "either" black hole has any physical meaning to us ever again. For all we know, the insides could be chocolate ice cream on one half of the now-double-sized Event Horizon, and pure neutronium on the other. It's meaningless to even pretend we know anything about that volume.
> If the black holes were moving fast enough, it should be possible for their event horizons to cross and then uncross,
No, that is not possible.
...because?
Time dilation is infinite at the even horizon, so anything that touches it, freezes for good.
The event horizon is not an object that can touch something, so why is that an objection to the idea of two event horizons crossing and uncrossing?
It's time itself that stops there. No matter what you want to move, you will have a problem moving it. It might be easier to understand that Democritean idea of space as literal nothingness is a bit old, in modern science space is field, i.e. solid matter (universe), particles move in it like sound for which steel is the most transparent medium, and nothingness is the most impenetrable, because there is no foothold there, we think it's empty because we can move freely in it.
Also most black holes have matter on the event horizon, because something fell on them. Maybe it can even touch, because this matter is frozen slightly above even horizon.
Infinities are typically indications of where a theory breaks down, not of something real.
Infinity there isn't abrupt, but steadily grows. Anything that approaches just does it slower and slower, and remains always finite, only exponential.
I don't know if there's ever been a more perfect setup for a your mother joke, but sometimes art is the brush strokes you don't make.
I'll counter Debussy ("the space between the notes ..." and all that :)
... and give it a go: "Yo mama is so big she can't even collide with a black hole" (or something ...)
All you really need to know for the moment is that the universe is a lot more complicated than you might think, even if you start from a position of thinking it’s pretty damn complicated in the first place.
Title needs an edit (maybe the clickbait algo): Astronomers Detect a Black Hole Merger That’s So Massive It Shouldn’t Exist - although, it's not a great title.
Thanks – I changed it (earlier today) to:
Black hole merger challenges our understanding of black hole formation
“Black hole merger detected that defies theoretical boundaries.”
Still not clear to me how this "contradicts known models for stellar evolution".
Our understanding of this universe constantly changes. We all know those - Earth is flat or it is center of universe, on and on.
The black hole is happening. So it exists. So either the observations are wrong or the undeying assumptions are wrong or math / physics we are using to make sense of the event is wrong.
Click-bait articles serve no purpose in advancing science.