Thoughts on electrically charged black holes

In summary: i.e., no matter what kind of stuff you can imagine throwing into the black hole (provided that stuff satisfies realistic physical conditions), you will never raise its charge-to-mass ratio to 1 or higher.
  • #1
mrspeedybob
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Suppose there exists a black hole with a large + electrical charge. The escape velocity for any given particle will depend on the net force on it, gravitational + electrical. It seems logical that the more positive a particles charge the lower its escape velocity will be from any given point. If the escape velocity for a neutral particle, such as a neutron or photon, would be > c then that particle is inside the black holes event horizon. But if a proton would have a lower escape velocity then it would seem possible for it to escape from a lower position then the photon could.

Is anything wrong with my logic so far? If not I have more questions about the implications of this but I don't want to get too speculative if there is some serious flaw with what I've said so far.
 
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  • #2
You are right that the electric force can counteract the gravitational pull to some degree. However, the horizon is still a fixed surface in space, the same for all observers, regardless of their charge. It represents the point at which gravity always "wins".

The reason for this is that physical charged black holes must always have their mass greater than their charge, M > Q in natural units. If one had a point mass with a charge Q > M, it would form a naked singularity, with no horizon at all. However, one can show that given a black hole with M > Q, there is no physical process that can raise Q > M...i.e., no matter what kind of stuff you can imagine throwing into the black hole (provided that stuff satisfies realistic physical conditions), you will never raise its charge-to-mass ratio to 1 or higher.

A charged black hole with M = Q is called "extremal", and is somewhat analogous to absolute zero (in that it is an ideal that cannot be reached by any physical process). In fact, the Hawking temperature of an extremal black hole is zero. A black hole with M = Q has its gravitational pull exactly balanced by its electric charge. In fact, one can easily find solutions to Einstein's equations for multiple extremal black holes, all of positive charge, distributed throughout space in any way you like: the reason this is possible is that the black holes, all having M = Q, exert no net force on each other. Such a solution is often called "BPS", after Bogomolnyi, Prasad, and Somerfeld, because it satisfies an extremal energy bound resembling those which BPS studied.
 
  • #3
Let me re-state what I think you said, and tell me if I got it right.

The definition of the event horizon is the surface from which nothing can escape. Since a charged black hole will repel like charges this brings the surface of the event horizon closer then it would otherwise be. The surface from which non-charged particles and light cannot escape would be unaffected but this surface would no longer be the event horizon.
 
  • #4
No. The surface from which positively-charged, negatively-charged, and neutral particles cannot escape is the same surface for all kinds of particles.
 
  • #5
mrspeedybob said:
Let me re-state what I think you said, and tell me if I got it right.

The definition of the event horizon is the surface from which nothing can escape. Since a charged black hole will repel like charges this brings the surface of the event horizon closer then it would otherwise be. The surface from which non-charged particles and light cannot escape would be unaffected but this surface would no longer be the event horizon.

The event horizon is defined in terms of null geodesics (light), period. It is simply the surface defined by null geodesics that can never escape to spatial infinity. Suppose the charged black hole is positive. A positive charge can still not escape from just below the horizon due to repulsion; despite repulsion, it still must follow a timelike path, which means once below a horizon by the tiniest amount it can never reach the horizion; it cannot overtake trapped light.
 
  • #6
Another way of looking at this is that it would require an infinite force (which is impossible) applied to a particle with non-zero mass to make it hover at the event horizon. Electrostatic repulsion can only supply a finite force, which is insufficient to prevent a charged particle fall through the horizon.
 
  • #7
Ben Niehoff said:
The reason for this is that physical charged black holes must always have their mass greater than their charge, M > Q in natural units. If one had a point mass with a charge Q > M, it would form a naked singularity, with no horizon at all.

Ben Niehoff said:
No. The surface from which positively-charged, negatively-charged, and neutral particles cannot escape is the same surface for all kinds of particles.

If Q>M forms a black hole with en event horizon of radius zero then can I assume that event horizon radius is a continuous function of Q and M where 0<Q<M? and that as Q decreases radius increases?

If what you say is true the relationship between event horizon radius and charge cannot simply a matter of electrostatics because then the point-of-no-return would depend on the charge of the test particle. What then is the relationship between black hole charge and event horizon radius? How does charge effect radius?

My understanding of GR is somewhat limited and most of it is based on SR and Einsteins equivalence principal. Perhaps if you could explain how the equivalence principal would hold true in the gravitational field of a charged body it would give me a stepping stone toward understanding the more extreme black hole scenario.
 
  • #8
mrspeedybob said:
If Q>M forms a black hole with en event horizon of radius zero then can I assume that event horizon radius is a continuous function of Q and M where 0<Q<M? and that as Q decreases radius increases?

If what you say is true the relationship between event horizon radius and charge cannot simply a matter of electrostatics because then the point-of-no-return would depend on the charge of the test particle. What then is the relationship between black hole charge and event horizon radius? How does charge effect radius?

My understanding of GR is somewhat limited and most of it is based on SR and Einsteins equivalence principal. Perhaps if you could explain how the equivalence principal would hold true in the gravitational field of a charged body it would give me a stepping stone toward understanding the more extreme black hole scenario.

Dr. Greg's explanation was based on SR, implicitly. GR includes as an axiom, that SR holds locally everywhere. So imagine just below the event horizon. Independent of charge, for a test particle to reach the event horizon is locally equivalent to catching up with light. The event horizon is a light-like surface. This is simply impossible, given SR. The principle of equivalence is irrelevant. This analysis explains that the electrostatics has nothing to do with point of no return. Imagine a negative charge just below the horizon of positive black hole, compared to a positive one. The finite difference in electrostatic force is irrelevant to the fact that it would take infinite force to reach the event horizon.

The event horizon does not shrink to zero as charge approaches the value for extremal black holes. Instead the event horizon simply disappears at this point (when charge exceeds the extremal value), leaving a naked singularity.

[For simplicity, I am deliberately leaving out discussion of Cauchy surfaces and ergospheres, sticking to outer event horizon.]
 
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  • #9
PAllen said:
Dr. Greg's explanation was based on SR, implicitly. GR includes as an axiom, that SR holds locally everywhere. So imagine just below the event horizon. Independent of charge, for a test particle to reach the event horizon is locally equivalent to catching up with light. The event horizon is a light-like surface. This is simply impossible, given SR.
Not sure what you are trying to say here, even in the simple Schwarzschild solution a test observer will momentarily cross the event horizon with a local velocity of c.
Are you saying this is not the case?
 
  • #10
Passionflower said:
Not sure what you are trying to say here, even in the simple Schwarzschild solution a test observer will momentarily cross the event horizon with a local velocity of c.
Are you saying this is not the case?

Only as seen by an observer at infinity. In their own frame, they are obviously not moving at all. However, the moment they cross the event horizon, an infinite force would be required to get back to the horizon. Actually, though, I'm not sure analogy is quite precise. Really, their light cones have rotated as they cross the horizon such that the singularity is in their inevitable future and the horizon is in their past. They can no more get back to the horizon than they can go back in time. (This light cone description is for the Schwarzschild solution. I have not studied the light cone structure of Kerr-Newman black holes; it may be similar, but I don't know for sure).
 
  • #11
PAllen said:
Only as seen by an observer at infinity. In their own frame, they are obviously not moving at all. However, the moment they cross the event horizon, an infinite force would be required to get back to the horizon. Actually, though, I'm not sure analogy is quite precise. Really, their light cones have rotated as they cross the horizon such that the singularity is in their inevitable future and the horizon is in their past. They can no more get back to the horizon than they can go back in time. (This light cone description is for the Schwarzschild solution. I have not studied the light cone structure of Kerr-Newman black holes; it may be similar, but I don't know for sure).

The same light-cone structure carries over to Kerr-Newmann and Reissner-Nordstrom black holes. In rotating black holes, the light cone first leans over (at the ergosphere), forcing co-rotation, before finally leaning inward (at the horizon).

In every kind of black hole, the horizon is a null surface where the spacelike vs. timelike roles of two basis vectors switch (except in extremal cases where the horizon is a double root, causing the two to immediately switch back again).
 
  • #12
Here is a graph showing various local velocities for test observers in a Schwarzschild solution. Clearly at r=rs they are all 1.

[PLAIN]http://img40.imageshack.us/img40/1793/velocities.png [Broken]
 
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  • #13
The phrase "local velocity of a test observer" makes no sense, as it is by definition zero.
 
  • #14
PAllen said:
Only as seen by an observer at infinity.
No, that is not correct, as dr/dt in Schwarzschild coordinates goes to zero when r->2M, and besides this is not a local velocity but a velocity at a distance.

It is also very easy to see that the local velocity of a test observer free falling from infinity at r=2M is c in Gullstrand–Painlevé coordinates. In fact for both the Schwarzschild and Gullstrand–Painlevé coordinates the local velocity is -sqrt(2M/r).
 
  • #15
Passionflower said:
No, that is not correct, as dr/dt in Schwarzschild coordinates goes to zero when r->2M, and besides this is not a local velocity but a velocity at a distance.

It is also very easy to see that the local velocity of a test observer free falling from infinity at r=2M is c in Gullstrand–Painlevé coordinates. In fact for both the Schwarzschild and Gullstrand–Painlevé coordinates the local velocity is -sqrt(2M/r).

What on Earth do you mean by local velocity? Velocity of what relative to what? I thought I was quite clear in my scenario about what is measured relative to what:

- a charge has just free fallen through the event horizon.
- sufficiently locally, its physics can be described as if it were at rest in a Minkowski inertial frame (this is axiomatically true in GR, at all points of the manifold; noting that the true singularity is not in the manifold).
- in this frame, getting back the event horizon would be equivalent to overtaking light (well, actually, worse; a spacelike path would be required to get back to the event horizon).

What is not clear about this? It is certainly true. I think you are giving unusual meaning to coordinate quantities.
 
  • #16
PAllen said:
What on Earth do you mean by local velocity? Velocity of what relative to what?
Let me ask you this, do you think that velocity is clearly defined in GR if it is not measured locally?

Relative to what? For instance relative to stationary or other observers. However when the velocity becomes c it is obviously c relative to all observers.
 
  • #17
Passionflower said:
Let me ask you this, do you think that velocity is clearly defined in GR if it is not measured locally?

Relative to what? For instance relative to stationary or other observers. However when the velocity becomes c it is obviously c relative to all observers.

Velocity is clearly defined as 4-vector. A 4-vector is quantity with an infinite number of coordinate representations. A local statement about a velocity measurement must entail two 4-velocities - that of the measuring device and that of the object being measured, both at the same event. Then you can say, unambiguously, that the object's velocity vector expressed in the frame of the instrument is what the instrument would measure.

I agree that velocity 'at a distance' is not well defined in GR. In that sense, I agree one of my statements was inaccurate: velocity observed by a distant observer is never well defined.

Velocity of a free fall body relative to a coincident hovering observer would be well defined, but it is not remotely the scenario I was describing.

The locally measured speed of a material body can never reach c. It is mathematically impossible, as this would mean there is a frame (of an instrument) in which a unit vector becomes a null vector.

I'm not sure what it is you think you are calculating, but it certainly can't be speed of free falling body relative to a hovering observer at the horizon because there is simply no such thing as a hovering observer at the horizon.
 
  • #18
PAllen said:
The locally measured speed of a material body can never reach c. It is mathematically impossible, as this would mean there is a frame (of an instrument) in which a unit vector becomes a null vector.

I'm not sure what it is you think you are calculating, but it certainly can't be speed of free falling body relative to a hovering observer at the horizon because there is simply no such thing as a hovering observer at the horizon.
We can have a hovering body momentarily at the EH but aside from that, we can easily calculate the velocity at the EH between a free falling observer falling at escape velocity and compare those to the velocities of a free falling observer from a given r value and from a free falling observer with an initial velocity at infinity. In both cases we calculate that the velocity is c.

But if you disagree and do not think it is c, I suppose you would not mind telling me the velocity between a free falling observer at escape velocity and an observer dropped at say R=10 at the EH?

We can even continue past the EH, while the spacetime is no longer stationary we could still calculate the local velocity between two observers.
 
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  • #19
Passionflower said:
We can have a hovering body momentarily at the EH but aside from that, we can easily calculate the velocity at the EH between a free falling observer falling at escape velocity and compare those to the velocities of a free falling observer from a given r value and from a free falling observer with an initial velocity at infinity. In both cases we calculate that the velocity is c.

A path even momentarily stationary at the event horizon has a lightlike tangent rather than a timelike tangent. Thus it would represent the frame of light, which is normally considered undefined in relativity.

No material instrument will ever locally measure the velocity of a body to be equal or greater than c. As I have explained, this is mathematically impossible in GR and SR (conventionally interpreted; let's not sidetrack into tachyons or the OPERA measurement).
 
  • #20
Passionflower said:
But if you disagree and do not think it is c, I suppose you would not mind telling me the velocity between a free falling observer at escape velocity and an observer dropped at say R=10 at the EH?

We can even continue past the EH, while the spacetime is no longer stationary we could still calculate the local velocity between two observers.

Sure you can continue timelike paths past the event horizon. Sure you can compute relative velocity of two objects passing the horizon at the same event with different infall histories. You will never get c for the relative velocity. To claim you do amounts to the claim that timelike unit vector expressed in some local frame becomes a null vector. This is just mathematically impossible. Whatever you are calculating it cannot be a velocity of material body measured locally by a material instrument.
 
  • #21
Passionflower said:
We can have a hovering body momentarily at the EH...
No you can't.

You've got all this the wrong way round. You cannot locally measure the velocity of anything relative to the event horizon, but you can locally measure the velocity of the event horizon relative to something that is falling through it, and the answer is always c (no matter what height the object was dropped from).

You cannot measure anything relative to the event horizon for exactly the same reason that a photon does not have a frame of reference.
 
  • #22
Thank you all for your replies.

I have spent the last 2 weeks contemplating this problem and what you have said. I'll try to walk through my thoughts in a logical way. Let me know if I have it right.

If a laser is shown downward from the roof of a building to the ground the light measured at the ground is slightly blue shifted. There are 2 equally correct ways to interpret this result
1. The light has gained energy as it has fallen into the the gravitational field. Since it's speed is fixed it gains the energy in the form of reduced wavelength
2. There must be a 1 to 1 correspondence between the number of waves emitted from the roof and the number received at the ground. Since the frequency at the ground is higher then 1 second at the ground must be longer then 1 second at the roof. This, I believe, is gravitational time dilation and is a well understood phenomena.

Now let's drop an experimenter (Bob) with a laser into a black hole while we (the other experimenters) remain at a distance. As the Bob falls seconds for him become longer compared to our seconds so we see the frequency of the light get lower and lower. As the laser approaches the event horizon we see the light become radio waves. We see the frequency drop to 1 cycle per second, then 1 cycle per day, then 1 cycle per year, etc.
From Bob's perspective, his laser is still emitting light at the same frequency, but as he looks outward he sees (in very blue-shifted light) the rest of the universe growing old at a rate of millions of years per tic of his watch, then billions, then trillions, all before he reaches the event horizon.

The 1'st take-away from this thought experiment is that from our perspective it makes no sense to talk about what happens inside or even at the event horizon because time there is infinitely dilated so from our perspective nothing happens. Relative to us black holes are frozen in time at the instant of their creation. It would be equally correct to say they are black because light cannot escape the gravity or to say they are black because all processes which might create light have been suspended. There is no singularity because from our perspective time, and the process of stellar collapse, stop the instant the density gets large enough to form an event horizon. Taking this logic 1 step further, no event horizon can form at all because as a star collapses its gravity increases, time dilation becomes more sever, and we on the outside see the process of collapse slow down and the light get redder until the light is undetectable and the surface from which it is emitted appears to be of constant size. In other word, it would become a black hole if time dilation had not infinitely slowed its collapse.

Since no event horizon can form it makes no sense to try to understand what happens at or within one.

Since this conclusion startled me I did some googling to try and find a refutation. I found places that say I'm right, for exactly the reasons I explained, and places that say I'm wrong, with explanations I couldn't understand. What is the mainstream view? If my logic is erroneous, where is the flaw?
 
  • #23
Your view is basically right. However, it is also right to say that the event horizon does form, because we can imagine observers that cross it.

The apparent paradox here really boils down to philosophy of science at this point. Which statement should we take to be "real"? Is there a black hole interior or not? Should we define "real" as "that which we can observe", or should we define "real" as "that which we can, using our theories, predict that someone falling in would observe"? So long as we stay outside the horizon, physics doesn't care one way or another.

I take the philosophical stance that nothing really falls into black holes; it all just collects right outside the event horizon. Many physicists share this view because it jibes with our ideas of black hole entropy and Hawking radiation.

But many physicists also take the other view, that we should take the Schwarzschild geometry as real, and the horizon is a perfectly regular part of the geometry, so infalling objects should simply cross it.

What we observe, watching from the outside, is the same either way.
 
  • #24
Ben Niehoff said:
Your view is basically right. However, it is also right to say that the event horizon does form, because we can imagine observers that cross it.

The apparent paradox here really boils down to philosophy of science at this point. Which statement should we take to be "real"? Is there a black hole interior or not? Should we define "real" as "that which we can observe", or should we define "real" as "that which we can, using our theories, predict that someone falling in would observe"? So long as we stay outside the horizon, physics doesn't care one way or another.

I take the philosophical stance that nothing really falls into black holes; it all just collects right outside the event horizon. Many physicists share this view because it jibes with our ideas of black hole entropy and Hawking radiation.

But many physicists also take the other view, that we should take the Schwarzschild geometry as real, and the horizon is a perfectly regular part of the geometry, so infalling objects should simply cross it.

What we observe, watching from the outside, is the same either way.

Is this equivalent to saying:

Within classical GR, the event horizon does form.

With semi-classical GR, the event horizon does not form.
 
  • #25
mrspeedybob said:
From Bob's perspective, his laser is still emitting light at the same frequency, but as he looks outward he sees (in very blue-shifted light) the rest of the universe growing old at a rate of millions of years per tic of his watch, then billions, then trillions, all before he reaches the event horizon.

This part isn't quite true. You have two competing rates for Bob - light from outside ever more blue shifted, but EH approaching ever faster. If you look at a Krukal Chart of the geometry, you can easily see that up until the moment of reaching the singularity, only finite external history has passed from Bob's point of view. For some external, stationary, light source, there is a definite last light that reaches Bob, the moment he reaches the singularity, and it is is not light from the infinite future.
 
  • #26
Ben Niehoff said:
I take the philosophical stance that nothing really falls into black holes; it all just collects right outside the event horizon. Many physicists share this view because it jibes with our ideas of black hole entropy and Hawking radiation.

In your philosophy, what happens to the matter at the center of collapsing body? It can't be frozen at the outside. So, it seems you posit that matter throughout the collapsed body is in some frozen state. What laws of physics apply to the central regions (I know, the presumed 'real' laws are not known yet)? If you assume anything like GR you cannot claim the interior is static, and the singularity theorems force the conclusion that catastrophic collapse occurs.

The big problem I see with frozen at horizon interpretations is that for a super-massive black hole, the internal density is not extreme at all - you could even have complete, normal stars inside the radius of last light, that would be seen to slow down, and then 'disappear' due to resdhift and light trapping (as the collapse proceeds). What physics is applying to what were perfectly normal stars that are now apparently frozen and invisible from the outside?

This type of argument leads me to favor the idea that new physics is unrelated to the event horizon. Instead, while the energy density inside the horizon is within the range of present day theories, normal physics proceeds. Sometime before or at the Planck scale, new physics takes over and suspends the collapse.
 
  • #27
PAllen said:
This part isn't quite true. You have two competing rates for Bob - light from outside ever more blue shifted, but EH approaching ever faster. If you look at a Krukal Chart of the geometry, you can easily see that up until the moment of reaching the singularity, only finite external history has passed from Bob's point of view. For some external, stationary, light source, there is a definite last light that reaches Bob, the moment he reaches the singularity, and it is is not light from the infinite future.

What's a Krukal Chart? I googled it and only found results for Krusal Chart which doesn't seem to pertain.
 
  • #28
mrspeedybob said:
What's a Krukal Chart? I googled it and only found results for Krusal Chart which doesn't seem to pertain.

I meant Kruskal chart. It is simply a very convenient set of coordinates for black hole geometry, allowing you to easily draw spacetime diagrams that span the horizon, and see the complete causal relationships. The following wikipedia article is a reasonable introduction:

http://en.wikipedia.org/wiki/Kruskal–Szekeres_coordinates

You can try reading the "qualitative features" section if you are afraid of the math.
 
  • #29
Where does the charge of a (charged) black hole reside?
 
  • #30
Mrspeedybob, you said:

"Taking this logic 1 step further, no event horizon can form at all because as a star collapses its gravity increases, time dilation becomes more sever, and we on the outside see the process of collapse slow down and the light get redder until the light is undetectable and the surface from which it is emitted appears to be of constant size."

A collapsing star will not increase in mass unless something is falling into it during the collapse, so time dilation will be more or less a constant throughout the collapse. The density will certainly increase, and effects of gravity will increase inside the collapsing areas, as mass will fall past it and start to contribut to the field there. Outside the original radius of the collapsing star, there will be no more than tremors in the gravitational field.

Am I wrong anywhere here?

Either way, very nice though experiment.
 

1. What is an electrically charged black hole?

An electrically charged black hole is a type of black hole that has an electric charge, in addition to its mass and angular momentum. This charge is caused by the presence of electrically charged particles within the black hole's event horizon.

2. How do electrically charged black holes differ from regular black holes?

Electrically charged black holes differ from regular black holes in that they have an additional property of electric charge. This charge affects the behavior of the black hole, including its gravitational pull and the way it interacts with other charged particles.

3. Can electrically charged black holes be detected?

Yes, electrically charged black holes can be detected through their effects on surrounding matter and light. Scientists can also look for telltale signs of electric charge in the black hole's accretion disk, which is a disk of matter that forms around the black hole as it pulls in surrounding material.

4. What are the implications of electrically charged black holes?

The presence of electric charge in black holes has significant implications for our understanding of gravity and the behavior of matter in extreme environments. It also has practical applications, such as in the study of charged particles in the universe and in the development of new technologies.

5. Are electrically charged black holes dangerous?

No, electrically charged black holes are not inherently dangerous. However, they can have powerful gravitational and electromagnetic effects on their surroundings, which can be dangerous for objects that come too close. The danger posed by a black hole depends on its size, mass, and surrounding environment.

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