Black Holes NOT Science?

In summary, the article asserts that the existence of black holes cannot be falsified, and therefore they do not qualify as science. Some people have argued this before, though it is a controversial topic.
  • #1
AdkinsJr
150
0
I read an interesting article which asserts that the existence of black holes cannot be falsified, and therefore they do not qualify as science. Has anybody heard this argument before? Any comments?
 
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  • #2
No one answered the question, though...

Black holes are objects and they most certainly exist as they have been observed countless times. In addition to the factual existence of the object, there is also a theory (many theories) about what, exactly, they are. These theories are pretty good but not yet complete (and may well never be). One particular aspect - what, exactly goes on behind the event horizon may be unfalsifiable due to its unobservability.
 
  • #3
Is there an equation that calculate how much gravitational force is needed to bend the light, say, to form an arc of x radius?

EDIT: Never mind. Some google search pointed me to the following url.
http://www.mathpages.com/rr/s6-03/6-03.htm

I don't think I'm knowledgeable enough to understand these complex equations. It's more than my brain can handle. Wish they were simpler.
 
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  • #4
russ_watters said:
Black holes are objects and they most certainly exist as they have been observed countless times. In addition to the factual existence of the object, there is also a theory (many theories) about what, exactly, they are.

I think you state this too strongly. We have much observational evidence for the existence of black holes, such as jets and accretion disks associated with supermassive black holes and other high energy phenomena, or the orbital motions of stars close to Sagittarius A. However, the defining feature, an event horizon, has never been observed.
 
  • #5
However, the defining feature, an event horizon, has never been observed.

But curiously enough you can observe something that would cause a "major problem." If you have something with a hard surface like a neutron star then stuff that falls on it will accumulate and if it is hydrogen eventually you get enough to cause a flare. With a black hole, there is no hard surface so stuff keeps falling in. The other thing is that to get a pulsar you have to have something getting emitted from the surface.

So if you have a very massive compact object which emits flares or is a pulsar, then you have some explaining to do. It so happens that we don't observe anything like that, and all of the accretion disks that do flare up and pulsars are objects which are below the black hole cutoff line.

Since you have observations that would falsify the existence of black holes (i.e. if you say an eight solar mass pulsar), it's science.
 
  • #6
matt.o said:
I think you state this too strongly...

However, the defining feature, an event horizon, has never been observed.
I'm not sure I'd call the event horizon "the defining feature", but semantics aside, I don't see why that would matter anyway. By analysis of gravity alone, you can identify a region of space where a massive object must reside. That object emits no light. Therefore, that object is a black hole. Not being able to visualize the boundary of that object doesn't change the fact that we know for certain we are observing (via its gravitational pull) a massive object that doesn't emit light.
 
  • #7
russ_watters said:
I'm not sure I'd call the event horizon "the defining feature", but semantics aside, I don't see why that would matter anyway.

Well, observationally speaking, since the event horizon is the "last frontier" beyond which nothing more can be observed, I would say then that it would be the best that can be done as far as providing ultimate proof of the existence of a black hole.

russ_watters said:
By analysis of gravity alone, you can identify a region of space where a massive object must reside. That object emits no light. Therefore, that object is a black hole. Not being able to visualize the boundary of that object doesn't change the fact that we know for certain we are observing (via its gravitational pull) a massive object that doesn't emit light.

By your line of reasoning, Dark Matter can also be classified as a black hole since it too is massive and neither emits nor absorbs light. All we can say currently is that there exists a massive, dense object. I believe that recent Very Long Baseline interferometric observations have come close to detecting an even horizon, but that's as close as we've come.
 
  • #8
for the gravitational field at a point to be strong enough to justify itself as a black hole, there must be an extremely dense point of charge. because light itself is a wave function, one can probably imagine that a body of charge which is compacted to extremely dense states will not be able to vibrate internally. remember that in infinitely high gravitational fields, "time" slows to zero, which is to say, there is no motion of charged bodies relative to each other. because an em wave is caused by a perturbation in a static electric field, when there are no vibrations, there is no light.

I believe that energy, on the whole, behaves in such a way that it likes to be in motion. this is why we can't achieve 0 K to date, energy just doesn't like remaining still[perhaps due to the fact that we ourselves on Earth are part of systems which change position relative to others, ie, our planet orbits in the soalr system, which in turn orbits the galactic bar, so on some tiny level, there is always likely to be some "universal shake" occurring due to our primary source of rotation]

Because energy must be very dense in a black hole, it becomes very hard to move. Since it wants to move, the black hole effect of sucking in whatever is around it may be the core energy bombarding itself with as much energy as possible to try and achieve vibration.

the event horizon itself may be a ball of vibration-less energy, that is to say, when things are sucked onto the event horizon, super huge gravity instantaneously stops any potential vibrations caused by the collision of absorbed matter with the core, including the vibrations in the absorbed particle itself, so the particle then becomes part of the event horizon, it goes "black".

black holes exist however, whether or not our understanding of them is correct, even if it turns out they weren't holes, the concept of the black hole is that of a region of high gravitational potential(ie bends light), coupled with no observable vibrations coming from within.
 
  • #9
matt.o said:
Well, observationally speaking, since the event horizon is the "last frontier" beyond which nothing more can be observed, I would say then that it would be the best that can be done as far as providing ultimate proof of the existence of a black hole.
But your complaint above was that the event horizon is not observable, wasn't it? Is the event horizon observable even in theory? If the event horizon is not observable, why should it be a problem that we can't observe it?

Anyway, this still doesn't trouble me at all. If you close your eyes and walk around your room, you might bump into something that feels like a chair. Is it a chair or do you have to see it with your eyes to know for sure?
By your line of reasoning, Dark Matter can also be classified as a black hole since it too is massive and neither emits nor absorbs light. All we can say currently is that there exists a massive, dense object. I believe that recent Very Long Baseline interferometric observations have come close to detecting an even horizon, but that's as close as we've come.
Is dark matter of a similar density to black holes?
 
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  • #10
russ_watters said:
But your complaint above was that the event horizon is not observable, wasn't it? Is the event horizon observable even in theory? If the event horizon is not observable, why should it be a problem that we can't observe it?

You should re-read my post.

russ_watters said:
Anyway, this still doesn't trouble me at all. If you close your eyes and walk around your room, you might bump into something that feels like a chair. Is it a chair or do you have to see it with your eyes to know for sure?

Well, if all scientists settled on logic like this, there would be nothing more to do, right?

russ_watters said:
Is dark matter of a similar density to black holes?

No, it is not, but your criteria was that to be defined as a black hole, an object just has to be massive and not emit light:

russ_watters said:
By analysis of gravity alone, you can identify a region of space where a massive object must reside. That object emits no light. Therefore, that object is a black hole.
 
  • #11
matt.o said:
You should re-read my post.
Uh, ok... You said:
However, the defining feature, an event horizon, has never been observed...

...the event horizon is the "last frontier" beyond which nothing more can be observed...
...so what is your point?
Well, if all scientists settled on logic like this, there would be nothing more to do, right?
Huh? Nothing I have said suggests that science has nothing more to do. There is a lot of work to be done on black hole theory.
No, it is not, but your criteria was that to be defined as a black hole, an object just has to be massive and not emit light:
Is dark matter "an object"? In any case, perhaps I was slightly too simplistic. So what? I think you get the point - I have no idea why you are being so argumentative.
 
  • #12
I'm trying to show you that statements like:

russ_watters said:
Black holes are objects and they most certainly exist as they have been observed countless times. In addition to the factual existence of the object, there is also a theory (many theories) about what, exactly, they are.

Are simply not true.
 
  • #13
I'm pretty convinced of the existence of black holes, but, have not heard any claim of proof to date. We know there are some suspiciously dense objects in the universe, and can at least infer they are probably black holes. That invisible spot in sagittarius with stars zipping around it at ridiculous velocities looks fairly compelling. An interesting point, however, is it appears extremely massive stars blow off too much mass to allow formation of stellar mass black holes. Neutron stars with masses in excess of about 1.33 solar mass are virtually unobserved to date - far short of the ~ 3 solar masses necessary to form a black hole. The smallest black hole detected to date weighs in at nearly 4 solar masses [http://www.space.com/scienceastronomy/080401-smallestblackhole.html] [Broken]. This is quite a mystery, imo. Where are all the 'tweeners'?
 
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  • #14
matt.o said:
I'm trying to show you that statements like:

Are simply not true.
Why didn't you say that before? Before you just said "too strong". I don't find it useful to be argumentative like that: if something is wrong, say it is wrong and explain why.

So far your quibbles have just been with the particulars of my admittedly simplistic definition. But I don't see those quibbles as being substantive/useful. Ie, no cosmologist would say an identified black hole is also consistent with dark matter, would they? Would a cosmologist identify this photo as a photo showing the aftermath of the creation of dark matter? http://chandra.harvard.edu/press/08_releases/press_041608.html

The wording of the article seems pretty unequivocable to me. They aren't saying that SGR A 'appears to be' or 'is theorized to be' a black hole. It is a black hole.
 
  • #15
Chronos said:
I'm pretty convinced of the existence of black holes, but, have not heard any claim of proof to date. We know there are some suspiciously dense objects in the universe, and can at least infer they are probably black holes. That invisible spot in sagittarius with stars zipping around it at ridiculous velocities looks fairly compelling. An interesting point, however, is it appears extremely massive stars blow off too much mass to allow formation of stellar mass black holes. Neutron stars with masses in excess of about 1.33 solar mass are virtually unobserved to date - far short of the ~ 3 solar masses necessary to form a black hole. The smallest black hole detected to date weighs in at nearly 4 solar masses [http://www.space.com/scienceastronomy/080401-smallestblackhole.html] [Broken]. This is quite a mystery, imo. Where are all the 'tweeners'?

Chronos, (as you've pointed out) "A fish cannot comprehend the existence of water. He is too deeply immersed in it."
 
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  • #16
Russ,

I think your conviction is understandable, but also too strong.

As Chronos said, we have observed curious things in the universe -- immense sources of energy, jets, accretion discs, large gravitational effects on other objects, even gravitational lensing -- which can only be understood as the consequences of extremely massive (and dense) objects.

Currently, the only theoretical candidate that we have to explain these observations is the black hole, as described by the general theory of relativity.

If you take the definition of "black hole" as "super dense body," then yes, there is observational proof that black holes exist. If you take the definition of "black hole" to mean the narrower "body as described by general relativity," then their existence is, at best, plausible. The actual nature of these super dense bodies could be radically different than anything we think we know today.

- Warren
 
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  • #17
russ_watters said:
Why didn't you say that before? Before you just said "too strong". I don't find it useful to be argumentative like that: if something is wrong, say it is wrong and explain why.

Actually, I think I did explain why I thought that statement was too strong. I'll admit that perhaps I was too strong in saying your statement was not true, and would have been better to say it was misleading.

russ_watters said:
So far your quibbles have just been with the particulars of my admittedly simplistic definition. But I don't see those quibbles as being substantive/useful. Ie, no cosmologist would say an identified black hole is also consistent with dark matter, would they? Would a cosmologist identify this photo as a photo showing the aftermath of the creation of dark matter? http://chandra.harvard.edu/press/08_releases/press_041608.html

My quibbles are with your penchant for dogmatically stating things. This is unscientific and does not help someone's understanding.

russ_watters said:
The wording of the article seems pretty unequivocable to me. They aren't saying that SGR A 'appears to be' or 'is theorized to be' a black hole. It is a black hole.

Ugh. This is a press release, and I also have problems with the way things are stated "as fact" in these things. Read the wording in the following journal articles: http://adsabs.harvard.edu/abs/2004Sci...304..704B" and note the use of phrases like "black hole candidate".
 
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  • #18
chroot said:
Russ,

I think your conviction is understandable, but also too strong.

As Chronos said, we have observed curious things in the universe -- immense sources of energy, jets, accretion discs, large gravitational effects on other objects, even gravitational lensing -- which can only be understood as the consequences of extremely massive (and dense) objects.

Currently, the only theoretical candidate that we have to explain these observations is the black hole, as described by the general theory of relativity.

If you take the definition of "black hole" as "super dense body," then yes, there is observational proof that black holes exist. If you take the definition of "black hole" to mean the narrower "body as described by general relativity," then their existence is, at best, plausible. The actual nature of these super dense bodies could be radically different than anything we think we know today.

- Warren

This is very well put, and conveys my thoughts too.
 
  • #19
We do not understand how matter behaves at extreme density, and there is no known way to replicate it in a laboratory. As Chroot noted, we may be quite surprised by the answer. The gap between neutron star masses and imputed 'black holes' remains very puzzling to me.
 
  • #20
russ_watters said:
No one answered the question, though...

Black holes are objects and they most certainly exist as they have been observed countless times.

I don't think so. It takes an infinite amount of time for matter to cross an event horizon. I think this quantifies the question "how long does it take a black hole to form?". I've had no informed responses on the this, so I can only make an ill-educated guess. Forever is a long time.

I would like to see the argument that a proto-black hole is measurably different than a black hole, and that observed objects touted as black holes in the pop-science press are measurably disinguishable.

Edit: I've jumped in without reading all the post, so forgive me if I am not in sync.
 
  • #21
Black holes are more than objects: they are timespace structures

When we ask 'Does X exist'? (existed, will exist) we assume some global 'NOW' in neutonian sense. It is not applicable to the BH.

To make it clear, formulate the question this way: Does the Blach Hole exist NOW?
Obviously, the question does not make any sense: SOME timeline trajectories from you WILL 'hit' the black hole (if you decide to fly there), others - will even never cross the lightcone from there.
 
  • #22
chroot said:
Russ,

I think your conviction is understandable, but also too strong.

As Chronos said, we have observed curious things in the universe -- immense sources of energy, jets, accretion discs, large gravitational effects on other objects, even gravitational lensing -- which can only be understood as the consequences of extremely massive (and dense) objects.

Currently, the only theoretical candidate that we have to explain these observations is the black hole, as described by the general theory of relativity.

If you take the definition of "black hole" as "super dense body," then yes, there is observational proof that black holes exist. If you take the definition of "black hole" to mean the narrower "body as described by general relativity," then their existence is, at best, plausible. The actual nature of these super dense bodies could be radically different than anything we think we know today.

- Warren
Warren, while you said my position is too strong, your description of the situation agrees exactly with what I said. I don't know quite what is going on here, but it seems like people are reading something in my posts that I didn't say.

Perhaps a more stark example of the same concept would help. The ancients observed many "planets" and gave them proper names like "Venus". They were woefully wrong about what, exactly they were viewing, nevertheless, they were viewing the same object we still call "Venus" and classify as a "planet" today.

So, fast forward 1000 years and assume turns out the exact body predicted by GR is woefully inadequate to describe what is being observed. All I am saying is that there is still an object SGR A - it's really there - and I even think that in 1000 years, they'll still call that object a "black hole". Whether they do or not, that doesn't change the fact that there really is an object there, just like regardless of what name and theory we use to describe Venus, it is still the same object the ancients were looking at.
 
  • #23
russ_watters said:
All I am saying is that there is still an object SGR A - it's really there - and I even think that in 1000 years, they'll still call that object a "black hole". Whether they do or not, that doesn't change the fact that there really is an object there, just like regardless of what name and theory we use to describe Venus, it is still the same object the ancients were looking at.

So far, even the blackness is theoretical. These objects typically emit large amounts of energy at some wavelengths (for quasars, this amount is almost impossibly huge), but it is usually assumed on theoretical grounds that this emission is coming from accretion disks around a black hole (as we cannot yet resolve the central component separately). If theory proves wrong, and significant energy is being emitted by the central object too, then I don't think that such objects would continue to be called "black".
 
  • #24
Chronos said:
Neutron stars with masses in excess of about 1.33 solar mass are virtually unobserved to date - far short of the ~ 3 solar masses necessary to form a black hole.

The 3 solar mass limit depends crucial on the equation of state for neutron star material which is unknown. If you assume that neutron star material is soft (which it may be), it's not hard to get a limit of 1.33 solar mass as the cutoff.

The smallest black hole detected to date weighs in at nearly 4 solar masses. This is quite a mystery, imo. Where are all the 'tweeners'?

It's not that much of a mystery. A neutron star has a surface and once material falls onto it, there are ways of getting the material off. Once material falls into a black hole it's going to stay there.
 
  • #25
Phrak said:
I don't think so. It takes an infinite amount of time for matter to cross an event horizon.

No it doesn't. Material falling into a black hole will take a finite (and quite small) time to pass through the event horizon to the singularity at which point who knows what happens.

From a distance, it appears that material will take an infinite amount of time to fall in, but that's something of an optical illusion.
 
  • #26
twofish-quant said:
but that's something of an optical illusion.

Uh, no.
 
  • #27
'optical' is not the right word
But I would not call the infitite time dilation for the fallign object real

Here is a best explanation of the BH I have ever seen
http://www.valdostamuseum.org/hamsmith/DFblackIn.gif [Broken]
 
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  • #28
Dmitry67 said:
'optical' is not the right word
But I would not call the infitite time dilation for the fallign object real

Here is a best explanation of the BH I have ever seen
http://www.valdostamuseum.org/hamsmith/DFblackIn.gif [Broken]

No, the plot is wrong. A black hole is as a spherical black body, that's it.
 
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  • #29
twofish-quant said:
No it doesn't. Material falling into a black hole will take a finite (and quite small) time to pass through the event horizon to the singularity at which point who knows what happens.

hmm. Matter will take an infinite amount of time to cross an event horizon.

There is no event horizon that is crossed for this in-falling frame of reference.

There is no clock that will record a local and finite elapsed time to cross an event horizon. You have to confuzzle coordinate systems to get this to work using the distant observer's coordinate singularity (the horizon) and the in-falling observer's clock.

From a distance, it appears that material will take an infinite amount of time to fall in, but that's something of an optical illusion.

Without this optical illusion there is no Hawking radiation.
 
  • #31
Bob_for_short said:
No, the plot is wrong. A black hole is as a spherical black body, that's it.

Look at the diagram. It is spherical.
 
  • #32
A black hole is defined as a dead star, whose escape velocity is greater than that of the speed of light.
 
  • #33
Phrak said:
hmm. Matter will take an infinite amount of time to cross an event horizon.

twofish-quant said:
Incorrect. See

http://antwrp.gsfc.nasa.gov/htmltest/gifcity/bh_pub_faq.html

Also it references Misner, Thorne, and Wheeler.

If you are going to throw things out like this you should provide a quote.

Matt talks about some "useful sense". I have no idea what is supposed to be useful about falling into a black hole. Apparently this doesn't mean a "physical sense".
 
  • #34
Phrak said:
Matt talks about some "useful sense". I have no idea what is supposed to be useful about falling into a black hole. Apparently this doesn't mean a "physical sense".

What in the world do you mean? I agree with twofish-quant.
Phrak said:
hmm. Matter will take an infinite amount of time to cross an event horizon.

This is wrong.
Phrak said:
There is no event horizon that is crossed for this in-falling frame of reference.

And this is wrong.
Phrak said:
There is no clock that will record a local and finite elapsed time to cross an event horizon. You have to confuzzle coordinate systems to get this to work using the distant observer's coordinate singularity (the horizon) and the in-falling observer's clock.

And this is wrong. Nothing has to be confuzzled. The in-falling observer's clock works just fine by itself.
 
  • #35
George Jones said:
What in the world do you mean? I agree with twofish-quant.

This is wrong.

And this is wrong.

And this is wrong. Nothing has to be confuzzled. The in-falling observer's clock works just fine by itself.

I keep getting these one liners as if this solves everything.

Please provide a world line that Contains a coordinate singularity.
 
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<h2>1. What exactly is a black hole?</h2><p>A black hole is a region in space where the gravitational pull is so strong that nothing, including light, can escape from it. It is formed when a massive star dies and its core collapses under its own gravity.</p><h2>2. How do we know black holes exist if we can't see them?</h2><p>While we cannot see black holes directly, we can observe their effects on the surrounding matter and light. For example, we can detect the gravitational lensing effect where the gravity of a black hole bends light from objects behind it.</p><h2>3. Can anything survive a black hole?</h2><p>No, anything that enters a black hole will be crushed and stretched due to the intense gravitational forces. However, some theories suggest that objects may be able to survive the outer edge of a black hole, known as the event horizon, but they would still be unable to escape.</p><h2>4. Are black holes constantly growing?</h2><p>Yes, black holes can grow in size by absorbing matter and merging with other black holes. However, they can also lose mass through a process called Hawking radiation.</p><h2>5. Can black holes be used for time travel?</h2><p>There is currently no evidence to suggest that black holes can be used for time travel. While they do have strong gravitational forces, the laws of physics as we know them do not allow for time travel through black holes.</p>

1. What exactly is a black hole?

A black hole is a region in space where the gravitational pull is so strong that nothing, including light, can escape from it. It is formed when a massive star dies and its core collapses under its own gravity.

2. How do we know black holes exist if we can't see them?

While we cannot see black holes directly, we can observe their effects on the surrounding matter and light. For example, we can detect the gravitational lensing effect where the gravity of a black hole bends light from objects behind it.

3. Can anything survive a black hole?

No, anything that enters a black hole will be crushed and stretched due to the intense gravitational forces. However, some theories suggest that objects may be able to survive the outer edge of a black hole, known as the event horizon, but they would still be unable to escape.

4. Are black holes constantly growing?

Yes, black holes can grow in size by absorbing matter and merging with other black holes. However, they can also lose mass through a process called Hawking radiation.

5. Can black holes be used for time travel?

There is currently no evidence to suggest that black holes can be used for time travel. While they do have strong gravitational forces, the laws of physics as we know them do not allow for time travel through black holes.

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