Understanding the Passage of Objects through the Event Horizon of a Black Hole

In summary: This may be because the object's continued momentum-energy drives it outward along a new geodesic that never intersects the event horizon. In summary, according to this information, an infalling physical object will never actually reach the event horizon.
  • #1
ShamelessGit
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Wikipedia says, "Likewise, any object approaching the horizon from the observer's side appears to slow down and never quite pass through the horizon, with its image becoming more and more redshifted as time elapses." So does this mean from the outside observer's perspective, that nothing ever actually falls into a black hole? Isn't this kind of strange? That would seem to mean that nothing (from our perspective) could ever actually fall into a black hole since its creation, it would just get stuck on the outside of the hole. But when things fall in they seem to disappear, don't they? Does it just redshift outside the range of any measurements? And from the perspective of the thing falling in, it just falls in and doesn't notice anything, right? But since it doesn't fall in from our perspective, does that mean that the inside of the event horizon has already experienced an infinite amount of time?
 
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  • #2
If it is true that the thing never actually falls into the black hole, then wouldn't the correct model for a black hole that has eaten things since its creation, from an observer's perspective, be a singularity at the center plus a hollow shell at the event horizon of the things it has eaten?
 
  • #3
In order to "see" the observer falling in, light incident on the infalling observer would have to reach our eyes or the infalling observer would have to send some kind of signal but these signals/light will get infinitely redshifted as the observer approaches the EH so the observer would get dimmer and dimmer and dimmer. Needless to say, the infalling observer will still pass through the EH in finite proper time, keyword being proper. This is a frame invariant quantity along the worldline of the infalling observer and it will be a finite value when the observer's e.g. purely radial free fall path from infinity to the EH itself is integrated along. I don't understand your last question, the above is by definition for eternal Schwarzschild black holes.

Things certainly do fall into black holes.
 
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  • #5
That other topic is NOT the same as this one. It gets frustrating when it seems like 2/3 of the people who answer my question don't understand what I'm talking about.

Wikipedia says that matter falling into the event horizon approaches, but never crosses the event horizon. This directly implies that observers outside the event horizon can never see anything cross the event horizon, even if the light wasn't red shifted. What is there not to understand?
 
  • #6
ShamelessGit said:
That other topic is NOT the same as this one. It gets frustrating when it seems like 2/3 of the people who answer my question don't understand what I'm talking about.

We understand what you're talking about; but after the four thousandth or so thread asking the same question, our answers can be a bit clipped sometimes.

ShamelessGit said:
Wikipedia says that matter falling into the event horizon approaches, but never crosses the event horizon.

Wikipedia is not a good starting point for actually learning about physics. Some Wiki pages are OK, but the only way to know which ones they are is to already know the subject matter well enough.

Here's a better starting point for an answer to your question:

http://math.ucr.edu/home/baez/physics/Relativity/BlackHoles/fall_in.html
 
  • #7
ShamelessGit said:
It gets frustrating when it seems like 2/3 of the people who answer my question don't understand what I'm talking about.
When more than half of the people who answer don't understand what you are talking about then it is a pretty good indication that you didn't ask your question clearly.

Here are some other related threads:
https://www.physicsforums.com/showthread.php?t=683076
https://www.physicsforums.com/showthread.php?t=656805
https://www.physicsforums.com/showthread.php?t=652845

The basic idea is that the idea that it takes an infinite amount of time to reach the EH is simply an artifact of a particular choice of coordinates. The coordinates are not themselves physical.
 
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  • #8
It took scientists some time to figure out what BH solutions to Einsteins equations meant...Einstein himself did not believe for some time that BH were 'physical'...

Two explanations of some mathematical complexities one doesn't normally see in short BH
descriptions: [To summarize a BH event horizon is a frame dependent measurement [i.e., relative]. Some see it, some don't.]

PAllen:
The technical definition of true event horizon makes it a feature of global geometry, completely independent of coordinates: the boundary separating null geodesics that reach null infinity from those that don't. Apparent horizons (local trapping surfaces) are coordinate dependent.
The following may be from Jambaugh of these forums:

Remember that an infalling physical object will have some mass or at least momentum-energy. So the full description of the space-time geometry along the future geodesic will no longer be static. The "infalling object never reaches the event horizon" derivation reflects an idealized limit as the object has zero effect on space-time. This zero effect and infinite time to infall should cancel to a finite outcome.
Here is some detail on 'coordinates' described in summary by Dalespam:

From Kip Thorne in BLACK HOLES AND TIME WARPS

[Torne here describes the Eddington-Finklestein coordinate system which shows the apparent singularity at the Schwarzschild radius is only a coordinate singularity not a true physical singularity.]

Finkelstein’s Reference Frame

when the star forms a black hole:
Finkelstein's reference frame was large enough to describe the star's implosion ...simultaneously from the viewpoint of far away static observers and from the viewpoint of observers who ride inward with the imploding star. The resulting description reconciled...the freezing of the implosion as observed from far away with (in contrast to) the continued implosion as observed from the stars surface...an imploding star really does shrink through the critical circumference without hesitation...That it appears to freeze as seen from far away is an illusion...General relativity insists that the star's matter will be crunched out of existence in the singularity at the center of the black...
http://www.jimhaldenwang.com/black_hole.htm
(separate file: Introduction to Mathematical Einstein)

Physical Interpretation of the Event Horizon

We found earlier that the Schwarzschild metric has a coordinate singularity at the event horizon, where the coordinate time becomes infinite. Recall that the coordinate time is approximately equal to the far away observer's proper time. However, a calculation using transformed coordinates shows that the infalling observer falls right through the event horizon in a finite amount of time (the infalling observer's proper time). How can we interpret solutions in which the proper time of one observer approaches infinity yet the proper time of another observer is finite?

The best physical interpretation is that, although we can never actually see someone fall through the event horizon (due to the infinite redshift), he really does. As the free-falling observer passes across the event horizon, any inward directed photons emitted by him continue inward toward the center of the black hole. Any outward directed photons emitted by him at the instant he passes across the event horizon are forever frozen there. So, the outside observer cannot detect any of these photons, whether directed inward or outward.

Consider two observers far from the black hole. Suppose they synchronize their watches, then one of them remains far from the black hole while the other descends slowly (at first) toward the event horizon. Then the time on the watch of the descending observer as he reaches and falls through the event horizon will be approximately equal to the time on the watch of the far away observer as she sees her companion disappear very near the event horizon.
 
  • #9
ShamelessGit said:
That other topic is NOT the same as this one. It gets frustrating when it seems like 2/3 of the people who answer my question don't understand what I'm talking about.

Wikipedia says that matter falling into the event horizon approaches, but never crosses the event horizon. This directly implies that observers outside the event horizon can never see anything cross the event horizon, even if the light wasn't red shifted. What is there not to understand?

You appear to be making a tacit assumption that all observers agree on what happens here. However, that is not the case; a far-away observer will never see anything fall across the horizon, while an observer falling in together with the object will not notice anything special at all ( for him the singularity is reached in a finite, well-defined time ) when he crosses the EH. This is perfectly fine - both are right, but only in their own frames of reference. In GR, not all observers necessarily agree on physical outcomes as viewed from their own frames of reference.
 
  • #10
As have been said, objects certainly fall into black holes and they don't notice anything special while crossing the event horizon (in the case of massive black hole, so that the tidal forces are negligible at EH). But for an static observer outside the BH, the infalling objects don't cross the EH, he will see them approaching it asymptotically forever (but because of the redshift, the light from them will eventually diminish in finite time).

Think it differently, in terms of the gravitational time dilation. For you, as an observer far away from the black hole, a clock near the event horizon will tick in much much slower rate than your clock. And the things there become slower and slower as that clock moves towards the event horizon, and eventually at the event horizon the time dilation is infinite. So the signals from there, sent in a constant rate according to their clock, won't be received in a constant rate from us. Each signal will be received later and later according to our clock, and finally the last signal from the event horizon will be received in infinite time...
 
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  • #12
Markus Hanke said:
In GR, not all observers necessarily agree on physical outcomes as viewed from their own frames of reference.

This is not correct. Actual outcomes, meaning observables like the amount of proper time elapsed on a particular clock, are the same in all reference frames that cover the appropriate portion of spacetime.

That last part in italics is the key: the reference frame (a better term would be "coordinate chart") in which an observer outside the horizon is at rest *cannot* cover the horizon or anything inside it. But any reference frame that does cover the horizon and the region inside will agree on what happens there.
 
  • #13
maxverywell said:
For you, as an observer far away from the black hole, a clock near the event horizon will tick in much much slower rate than your clock. And the things there become slower and slower as that clock moves towards the event horizon, and eventually at the event horizon the time dilation is infinite. So the signals from there, sent in a constant rate according to their clock, won't be received in a constant rate from us. Each signal will be received later and later according to our clock, and finally the last signal from the event horizon will be received in infinite time...

This isn't strictly correct, because the statements you are making, strictly speaking, only apply to clocks that are static--i.e., they stay at the same radius above the horizon. A clock can't be static at or inside the horizon. And the time dilation you are talking about, strictly speaking, can't be defined for clocks that are not at rest relative to each other, so it doesn't apply to clocks that are falling inward, even if they are outside the horizon.
 
  • #14
PeterDonis said:
This isn't strictly correct, because the statements you are making, strictly speaking, only apply to clocks that are static--i.e., they stay at the same radius above the horizon. A clock can't be static at or inside the horizon. And the time dilation you are talking about, strictly speaking, can't be defined for clocks that are not at rest relative to each other, so it doesn't apply to clocks that are falling inward, even if they are outside the horizon.

Can't we relate the time interval ##\Delta \tau_{AB}=\tau_A-\tau_B## between the events of emission of two signals A and B, as measured by a freely falling observer outside the EH of a Schwarzschild BH (##\tau## is his proper time), to the time interval ##\Delta t##of an static observer at infinity(his proper time is the Schwarzschild coordinate ##t##)?
 
  • #15
maxverywell said:
Can't we relate the time interval ##\Delta \tau_{AB}=\tau_A-\tau_B## between the events of emission of two signals A and B, as measured by a freely falling observer outside the EH of a Schwarzschild BH (##\tau## is his proper time), to the time interval ##\Delta t##of an static observer at infinity(his proper time is the Schwarzschild coordinate ##t##)?

Sure - they're numbers, we can define a mapping between them. But what physical significance does this relationship have?
 
  • #16
You might be interested in this related exercise from Padmanabhan's text:

problem_8_4.png
 
  • #17
Here's a nice diagram from Carroll's notes in GR.
It clearly demonstrates my point.

https://www.physicsforums.com/attachment.php?attachmentid=60078&d=1372967470

What I asked is if it's possible to find a relation between ##\Delta \tau_1## and the ##\Delta \tau_2##. The problem here is that one observer is infalling. I know how to find the relation for the case when both observers are static.
 
  • #18
Shamless...by now you should be pretty confused! Every time I read one of these BH thingys I pick up a tad more...especially from thus guy...

PeterDonis posts:
That last part in italics is the key: the reference frame (a better term would be "coordinate chart") in which an observer outside the horizon is at rest *cannot* cover the horizon or anything inside it.

That's a 'crazy' statement, but is an appropriate example of 'some mathematical complexities' I mentioned in a post above. It reminds me of one thing I have learned: Unless you are a local inertial observer, things get weird. Looking at things from an 'infinite distance' or accelerating outside an event horizon to remain 'stationary' can fortell odd observations.

Think as a crude example, about hearing thunder. Say you are two miles away and a buddy is one mile away from the lightning strike. You'll never resolve your differences in recording WHEN the event happened unless you adjust for the travel time of sound. In SR, GR and cosmology, each gets successively more detailed trying to describe distance, speed, even energy.

'At rest' in PeterDonis description above means accelerating to remain in place. Such an observer will generally see something very different from an adjacent [local] free falling observer.
 
  • #19
maxverywell said:
https://www.physicsforums.com/attachment.php?attachmentid=60078&d=1372967470

Actually I think that the light rays (dashed curves) in this diagram are drawn incorrectly.
I think that the ##\Delta t## between two consequent dashed curves should be constant.
 
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  • #20
ShamelessGit said:
That other topic is NOT the same as this one. It gets frustrating when it seems like 2/3 of the people who answer my question don't understand what I'm talking about.

Wikipedia says that matter falling into the event horizon approaches, but never crosses the event horizon. This directly implies that observers outside the event horizon can never see anything cross the event horizon, even if the light wasn't red shifted. What is there not to understand?

Red shfiting is NOT logically sepearate from the ratio of "time of arrival" to "time of emission". In fact, redshift is the ratio of the change time of emission to ##\Delta \tau_{emission}## to the change in time of arrival ##\Delta \tau_{arrival}##, where the ##\tau## symbol represents proper time.

I haven't read the previous discussion, because after 5,000 times of going through this, I do get a bit tired of it. But I thought I'd point out how a discussion about redshfit actually WAS answering your question , even if you didn't quite realize it.

I am concerned that you might not know what I mean when I say proper time. Is the term familiar to you, and do you understand the difference between proper time and coordinate time? If not, it would be a good place to start understanding what people have been saying.


I'll say one more thing. If an observer is at rest a long way away from a black hole, the proper time (there's that word again!) before they reach the event horizion can be calculated, and is finite. The Schwarzschild time, which is a coordinate time assigned to the event of "falling into the black hole" is infinite. The proper time according to an infalling observer is not.

Saying that "the infalling observer never crosses the event horizon" is a bad idea, because it suggests that both times should be infinite. And, they're not. The proper time is finite.

Now that I've hopefully established some relevance of why you should care about the difference between proper time and cooridnate time, I'll try to give a (very brief) sketch of the difference between them.

Coordinate times simply assign a number, a label, to an event. In General Relativity, the laws by which this assignment made are very lax, because of this laxness the assignement of coordinate times don't have any real physical significance. Coordinate time can (and often does) advance at a different rate than the time which actual clocks keep. In particular Schwarzschild time is a coordinate time, and changes in Schwarzschild time aren't the same time as what actual clocks keep.

The time which actual clocks keep is called proper time. The clock must be directly present at the same (or nearly the same) spatial location of all events being measured in order for proper time to be applicable. If the clock was not present at all events, one is actually using a coordinate time, and not proper time.
 
  • #21
PeterDonis said:
This is not correct. Actual outcomes, meaning observables like the amount of proper time elapsed on a particular clock, are the same in all reference frames that cover the appropriate portion of spacetime.

True, bad choice of words on my part. What I meant to say was that the observers don't agree in that the infalling one sees himself crossing the horizon, whereas the one stationary at infinity does not.
 
  • #22
The diagram I was talking about:
 

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  • #23
maxverywell said:
Actually I think that the light rays (dashed curves) in this diagram are drawn incorrectly.
I think that the ##\Delta t## between two consequent dashed curves should be constant.

No, it isn't, because the later light rays are emitted from a smaller radius (closer to the horizon) than the earlier ones. So it takes them longer to get out to the distant observer even according to the ##t## coordinate.
 

What is a passing through event horizon?

A passing through event horizon is a point of no return in a black hole where the gravitational pull becomes so strong that nothing, not even light, can escape. It marks the boundary between the outside of a black hole and its interior.

What happens when an object passes through an event horizon?

When an object passes through an event horizon, it is pulled into the black hole and its mass becomes part of the singularity at the center. This process is known as spaghettification, where the intense gravitational force stretches the object into long, thin strands.

Can anything escape from an event horizon?

Once an object has passed through an event horizon, it is impossible for anything to escape. The gravitational pull is so strong that not even light can escape, making it impossible for any information or matter to leave the black hole.

What is the size of an event horizon?

The size of an event horizon varies depending on the mass of the black hole. Generally, the more massive a black hole is, the larger its event horizon will be. For example, the event horizon of a black hole with the mass of our Sun is about 3 kilometers in diameter, while a supermassive black hole's event horizon can be billions of kilometers wide.

Is it dangerous to pass through an event horizon?

Yes, it is extremely dangerous to pass through an event horizon. The intense gravitational forces and spaghettification would tear apart any object, making it impossible for anything to survive the journey. It is also impossible to escape once inside, so it is best to avoid getting too close to an event horizon.

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