Could a Particle Accelerator Create a Black Hole That Destroys Earth?

In summary, the fear of a black hole being created by the CERN accelerator that would swallow Earth is not possible in practice or in principle, as a microscopic black hole would have no more gravity than the particles that created it. Additionally, a black hole with the mass of two protons would have a very short lifetime and could not consume enough matter to pose a threat.
  • #1
DaveC426913
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This may be condensed matter physics topic, but I'm looking for a layperson answer.

Scares of the CERN accelerator creating a black hole that swallows Earth are in the news once again.
https://www.newsweek.com/earth-shrunk-tiny-hyperdense-sphere-particle-accelerators-1145940
From 10 years ago:
https://www.newscientist.com/article/dn13555-particle-smasher-not-a-threat-to-the-earth/

I know it is not possible for an accelerator to produce such a black hole in practice. But surely it's impossible even in principle.Surely, a particle accelerator creating a tiny black hole that could grow to swallow the Earth would violate the law of conservation of energy.

Whatever object was created would only have as much energy in it as was supplied. I mean, you can't have a free lunch here.

Contrarily, an atom bomb brings atoms together that already have energy in the form of bonds that hold the heavy elements together; all the bomb is doing is releasing that energy.

Where would a tiny black hole get the energy to destroy the Earth? Is it a wholly exothermic phenomenon? i.e. the energy is already there in the atoms, and a particle accelerator is simply releasing it, allowing atoms to fall together and coalesce at the singularity?

The implication of that is that all mass exists in a state of instability, on one side of an "energy hill" - the hill preventing it from collapsing into a BH - and all we have to do is just crush it enough to release that inherent energy? That seems wrong.Again, contrarily, the universe can make black holes easily enough because it is effectively an open system; there is always enough energy, and occasionally a whole bunch of it can end up in one place.

Is my thinking sound?
 
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  • #3
Thanks. But this is really an academic question on my part about the physics. Not concerned about why this is in the news.
 
  • #4
Then it should be in Quantum Physics, shouldn't it?

... and the quoted article sheds some light on the unsuccessful search for strangelets.
 
  • #5
DaveC426913 said:
Where would a tiny black hole get the energy to destroy the Earth?

A tiny black hole would have no more gravity than the particles that created it. Black holes, in general, have the same gravity as the stars that created them. It's a myth that they suck in everything through some sort of super-gravity.

What is different about a black hole is that if you fall into one, you do not stop by hitting the surface of a star. In the case of the star, you collide with its surface. In the case of the black hole, you continue to fall and experience greater gravity - but only after you get closer than was possible with the star.
 
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  • #6
A microscopic black hole would rapidly evaporate into Hawking Radiation. Its lifetime would be very short, and proportional to the mass. A black hole with the mass of two protons, would have a lifetime of ? (nanoseconds?) I wager that others here on PF can give us the exact number.
 
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  • #7
PeroK said:
It's a myth that they suck in everything through some sort of super-gravity.

What is different about a black hole is that if you fall into one, you do not stop by hitting the surface of a star. In the case of the star, you collide with its surface. In the case of the black hole, you continue to fall and experience greater gravity - but only after you get closer than was possible with the star.
Yep. This I know. I have a history (including diagrams!) of explaining this to curious forum members.
anorlunda said:
A microscopic black hole would rapidly evaporate into Hawking Radiation.
Yes.

I'm just trying to figure out whether it's safe to say it can't happen because there simply isn't an Earth-swallowing-black-hole's amount of energy available.

Perhaps another way to phrase the question is: how massive must a black hole be before it can result in a runaway reaction?

I guess if you had a micro BH and just kept feeding it matter, it would always be able to grow. Which means my premise is faulty.
 
  • #8
I think I've got it now.

The energy required to crush the Earth is already present in the form of gravitational potential energy. Every atom that is not at the CoG wants to fall to the CoG. So, if a cavity is formed by the BH eating what's around it (granting the BH lives long enough), more matter will fall toward it, which will then make it available to be consumed by the BH.

i.e. assuming the BH does not immediately evaporate*, it will result in a runaway reaction, consuming the Earth. So, my premise is faulty.*But that is not a good assumption.
 
  • #9
PeroK said:
A tiny black hole would have no more gravity than the particles that created it.
I think this is the basic answer to the question. There are many stars and planets that orbit black holes and which are in no danger of being 'sucked in'.
 
  • #10
sophiecentaur said:
There are many stars and planets that orbit black holes and which are in no danger of being 'sucked in'.
While true, that is a very different scenario from a BH on/in Earth.

Material around BH in space has plenty of lateral motion, keeping matter from falling directly toward the BH.

The matter of Earth starts off stationary wrt the BH; the first thing it's going to do, when it can, is fall straight down toward the BH. And all the rest of the Earth's matter is poised just above that, waiting to fall straight down too (actually, explode straight down, since it's under a huge amount of compression).

Essentially, a BH in the Earth doesn't need to have any gravity at all. The Earth's matter will come straight to it.

OK, I've corrupted the scenario slightly. I'm now describing a BH at the centre of the Earth, as opposed to one in a CERN lab near the surface.

Still, the point remains - a BH on Earth is embedded in matter that is stationary wrt to it - not in an orbit.
 
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  • #12
DaveC426913 said:
a BH on Earth is embedded in matter that is stationary wrt to it

Yes, and this does make a significant difference.

The reason is that there is a theorem called Buchdahl's Theorem, which says, in effect, that no matter can be in hydrostatic equilibrium if it is closer to a black hole's horizon than 9/8 of its Schwarzschild radius. Any matter that is present within that radius must fall into the hole. (Note that we are assuming the matter does not contain things like rocket engines that can provide thrust in the absence of hydrostatic equilibrium; for the case under discussion this should be a good assumption. :wink:)

So if a black hole is embedded in matter, it is guaranteed to gain mass; and as it gains mass, the radius within which matter must fall into it grows, so the process is self-reinforcing and will continue as long as there is matter close enough to the hole.

For a hole of sufficiently small mass, the rate of mass gain from the above process should be smaller than the rate of mass loss via Hawking radiation. However, even then there are some possible caveats. First, it's not clear exactly how Hawking radiation is supposed to work for a hole embedded in matter; all of the theoretical work on Hawking radiation assumes a hole surrounded by vacuum. But let's suppose that the hole being embedded in matter doesn't significantly affect the rate of Hawking radiation. That still leaves a second point: the radiation can't escape to infinity, because the hole is surrounded by matter. What will happen is that the matter surrounding the hole will heat up (to roughly the Hawking radiation temperature). It's not clear that all of the energy radiated as Hawking radiation will actually end up escaping, instead of being trapped in the surrounding matter and ultimately falling back into the hole.
 
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  • #13
sophiecentaur said:
There are many stars and planets that orbit black holes and which are in no danger of being 'sucked in'.

The response that @DaveC426913 gave to this is correct: while it's true, it's a very different scenario from the one he was proposing. (See my previous post just now for some more on his scenario.)
 
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  • #14
DaveC426913 said:
I'm now describing a BH at the centre of the Earth, as opposed to one in a CERN lab near the surface.

Even with the lab at the surface, there will still be plenty of matter within 9/8 of the Schwarzschild radius, so the hole will gain mass (assuming Hawking radiation is small enough not to counterbalance this--see post #12). The difference between the lab at the surface and the BH at the center is that, at the surface, the hole will start to move: matter can't stop it from moving because it just swallows matter in its path. At least as a first approximation, the hole will assume an elliptical orbit about the Earth's center with an apogee equal to the Earth's radius and a perigee that I haven't calculated but which will be determined by its tangential velocity at the lab at the surface (and which will be pretty far inside the Earth since that tangential velocity is going to be a lot less than orbital velocity at the surface). Whereas the BH at the center will just sit there as it accretes mass.
 
  • #15
Ive heard it said elsewhere that there are collisions taking place on the Earth every day with energies greater than those being generated at the LHC. I believe this was a reference to cosmic rays. So, even if it is possible for Earth-devouring black holes to be generated in a collider, it is far less probable than the chance that one of these tiny terrors will simply happen on its own some day. The fact that this has not yet occurred points to the likelihood that it cannot. But, even if our planet’s continued existence is merely a matter of probability, that probability is hardly effected at all by the very few collisions happening in accelerators around the world.

Therefore,The experiments at CERN either
a) do not constitute any risk at all, or
b) do not appreciably add to a risk that exists independently of that facility.

(Maybe that explains Dark Matter!)
 
  • #16
The question remains as to how long such a process might take. It would presumably be a bit 'runaway' so it could well be over before we could have time to notice it and to worry about it. The matter in the vicinity of the BH would be molten so it would fall down with no mechanical support.
 
  • #17
sophiecentaur said:
The question remains as to how long such a process might take. It would presumably be a bit 'runaway' so it could well be over before we could have time to notice it and to worry about it.
If you removed the Earth and replaced it with a black hole of equivalent mass, you'd be talking about [very] roughly ten minutes of free fall time to arrive at the singularity. So that's one simple lower bound on how long the process would take. I would be expecting billions (trillions? More?) of years to smoosh the Earth into a black hole that starts with a sub-atomic size.

Just because something is fluid, that does not remove all mechanical support. The water in your bathtub does not drain instantly.
 
  • #18
jbriggs444 said:
If you removed the Earth and replaced it with a black hole of equivalent mass, you'd be talking about [very] roughly ten minutes of free fall time to arrive at the singularity. So that's one simple lower bound on how long the process would take. I would be expecting billions (trillions? More?) of years to smoosh the Earth into a black hole that starts with a sub-atomic size.

Just because something is fluid, that does not remove all mechanical support. The water in your bathtub does not drain instantly.
Sufficient time for the Human Race to go completely loopy and try for a Star Ship escape then?
 
  • #19
anorlunda said:
A black hole with the mass of two protons, would have a lifetime of ?

The relevant formula is:

##T(M) = 5120 \frac{\pi G^2 M^3}{\hbar c^4}##

So for two protons the evaporation time will be about 3 x 10-96 seconds.

For one gram of matter, about 8 x 10-26 seconds. I wonder how that compares to the reaction rate of a typical nuclear explosion?
 
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  • #20
gneill said:
The relevant formula is:

T(M)=5120πG2M3ℏc4T(M)=5120πG2M3ℏc4T(M) = 5120 \frac{\pi G^2 M^3}{\hbar c^4}

So for two protons the evaporation time will be about 3 x 10-96 seconds.

Thank you @gneill. I would like to elaborate on that because I find this whole scenario unrealistic.

The key is to focus on the initial mass of the BH. Before it reaches appreciable mass, it must begin with the collision of two hadrons. (Events with more than two particles collapsing simultaneously are far less likely.)

So two protons collide, form a BH, and evaporate in 3x10-96 seconds.

The energy released in an explosion of 2*1.67*10−27 kg*c2 = 3*10-10 joules.

The average power of the energy release is 1077 GW. I did not compute the power density, or the flux of escaping radiation.

Would the BH suck in more mass before complete evaporation? Well, the time is very short. The density of mass in the collider beam is very small. And the radiation pressure on incoming particles would either deflect them, or slow them down enough to miss the 3x10-96 second window. Given these extreme numbers, I expect that classical calculations totally fail. We would need QED and perhaps GR to calculate the behavior of nearby particles in that time window with those conditions. My guess is that the probability of absorbing even one more particle is very small.

Does that sound realistic?
 
  • #21
sophiecentaur said:
Sufficient time for the Human Race to go completely loopy
Don't have to wait for that.
 
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  • #22
anorlunda said:
Does that sound realistic?
Looks reasonable to me.
 
  • #23
jbriggs444 said:
If you removed the Earth and replaced it with a black hole of equivalent mass, you'd be talking about [very] roughly ten minutes of free fall time to arrive at the singularity. So that's one simple lower bound on how long the process would take. I would be expecting billions (trillions? More?) of years to smoosh the Earth into a black hole that starts with a sub-atomic size.

Just because something is fluid, that does not remove all mechanical support. The water in your bathtub does not drain instantly.
But the centre of theEarth is under pressure. A bathtub at the centre of the Earth would "drain" explosively - in microseconds -cwith such a pressure differential.

Why would it take billions/trillions of years? (Presumably, the vast majority of that time would be spent at subatomic size, with the last macro-scale gobbling happening in just moments.)
With matter crushing down on it at millions of atmospheres, why would it take so long to grow?
 
  • #24
gneill said:
Looks reasonable to me.

LOL :wink: I meant does it sound like a realistic scenario for squishing the Earth?
 
  • #25
DaveC426913 said:
But the centre of theEarth is under pressure. A bathtub at the centre of the Earth would "drain" explosively - in microseconds -cwith such a pressure differential.
An ordinary bathtub with a one inch radius spigot would drain quickly under such a pressure differential, certainly. But an Earth-sized bathtub draining through a sub-atomic orifice? Let's see that calculation.

We already know that we have a 10 minute lower bound.

Edit: @PeterDonis has more precisely quoted this particular lower bound at approximately 20 minutes.
 
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  • #26
gneill said:
for two protons the evaporation time will be about 3 x 10-96 seconds.

The relevant energy is not the rest energy of two protons, but the energy in the lab frame of the collision. For the LHC, that's now about 13 TeV IIRC. That's about 13,000 proton masses, which increases the time by a factor of about ##10^{12}##. That doesn't change the qualitative conclusion, but I think it's worth noting the correct numbers.
 
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  • #27
anorlunda said:
LOL :wink: I meant does it sound like a realistic scenario for squishing the Earth?
It sounds like a reasonable argument against creating self-sustaining microscopic black holes.
 
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  • #28
anorlunda said:
My guess is that the probability of absorbing even one more particle is very small.

I would agree; for a hole of the size that could hypothetically be produced by the LHC, the evaporation time is so short that it should dominate anything else in the dynamics.
 
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  • #29
DaveC426913 said:
the centre of theEarth is under pressure. A bathtub at the centre of the Earth would "drain" explosively - in microseconds -cwith such a pressure differential.

No, it wouldn't, because the matter starts out at rest and it will take time for it to cover the distance to the center. Roughly speaking, if we assume that the matter has zero viscosity for this purpose (since it's all going down the hole at the center so matter just crossing the horizon won't "push back" against matter behind it), the time for the matter at the Earth's surface to reach the center and get swallowed by the hole should be about 20 minutes--one fourth of the free-fall orbit time.
 
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  • #30
PeterDonis said:
I would agree; for a hole of the size that could hypothetically be produced by the LHC, the evaporation time is so short that it should dominate anything else in the dynamics.
But aren't the products of a scattering process still very fast, say near ##c## such that there would be enough time to hit the wall?
 
  • #31
fresh_42 said:
aren't the products of a scattering process still very fast, say near ##c## such that there would be enough time to hit the wall?

If we assume a collision of equal energy particles moving in opposite directions (which AFAIK is the normal setup in an experiment like the LHC), a black hole that was produced could have zero momentum. That doesn't happen with normal collision products because the energy of the products is so much larger than their rest energy that they have to be moving very fast. But a collision that produced a black hole could have all of the collision energy converted to rest energy of the hole.

Also, even if the hole were moving at close to ##c##, its evaporation time is so short that it wouldn't be able to move very far--only about ##10^{-75}## meters, based on the numbers in post #26.
 
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  • #32
PeterDonis said:
I would agree; for a hole of the size that could hypothetically be produced by the LHC, the evaporation time is so short that it should dominate anything else in the dynamics.
Not to mention that the Schwarzschild radius of such a black hole would be on the order of 10-121 nm, far smaller than the size of a typical atom. Presumably the BH could pass through a given atom without eating anything much as a comet can pass through our solar system without hitting a planet.
 
  • #33
gneill said:
Not to mention that the Schwarzschild radius of such a black hole would be on the order of 10-121 nm

I don't think it's quite that small. If ##M## is 10,000 proton masses, or about ##10^{-23}## kg, then ##2GM / c^2## gives ##2 \times 6.67 \times 10^{-11} \times 10^{-23} / 9 \times 10^{16}##, or about ##10^{-50}## m, which is ##10^{-41}## nm. Still very, very small compared to the sizes of atoms or even nuclei, of course.

Another wrinkle to consider is that a black hole of mass that small--well under the Planck mass--might not even be possible, depending on how quantum gravity turns out.
 
  • #34
PeterDonis said:
I don't think it's quite that small. If ##M## is 10,000 proton masses, or about ##10^{-23}## kg, then ##2GM / c^2## gives ##2 \times 6.67 \times 10^{-11} \times 10^{-23} / 9 \times 10^{16}##, or about ##10^{-50}## m, which is ##10^{-41}## nm. Still very, very small compared to the sizes of atoms or even nuclei, of course.
Aurgh. Thanks for catching that. I'd just done the calculation for the apparent volume enclosed by the Schwarzschild radius and picked up that number thinking it was the radius calculation I'd done next to it. Very sloppy on my part.

Another wrinkle to consider is that a black hole of mass that small--well under the Planck mass--might not even be possible, depending on how quantum gravity turns out.
That's an interesting thought; Nature protecting itself from random micro black holes gobbling up all the matter.
 
  • #35
gneill said:
That's an interesting thought; Nature protecting itself from random micro black holes gobbling up all the matter
Or to add another fantasy: It happened so often before until the right setup has been left.
 
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<h2>1. Could a Particle Accelerator Create a Black Hole That Destroys Earth?</h2><p>No, it is highly unlikely that a particle accelerator could create a black hole large enough to destroy Earth. The energy levels produced by particle accelerators are much lower than those required to create a black hole. Additionally, any black holes created would be extremely small and would evaporate almost immediately due to Hawking radiation.</p><h2>2. Is there any evidence that a particle accelerator could create a black hole?</h2><p>No, there is no scientific evidence to suggest that a particle accelerator could create a black hole. Theoretical calculations and simulations have shown that the energy levels produced by particle accelerators are not high enough to create a black hole.</p><h2>3. Could a black hole created by a particle accelerator grow and eventually destroy Earth?</h2><p>No, even if a black hole were to be created by a particle accelerator, it would not be able to grow and destroy Earth. The Earth's gravity is not strong enough to be affected by a small black hole, and it would eventually evaporate due to Hawking radiation.</p><h2>4. Are there any safety concerns regarding particle accelerators and black holes?</h2><p>No, there are no safety concerns related to black holes and particle accelerators. As mentioned before, the energy levels produced by particle accelerators are not high enough to create a black hole, and any black holes that may be created would be too small and short-lived to pose any danger.</p><h2>5. What are the potential benefits of studying black holes with particle accelerators?</h2><p>Particle accelerators can provide valuable insights into the behavior of matter and energy in extreme conditions, such as those found in black holes. Studying black holes with particle accelerators can help us better understand the fundamental laws of physics and potentially lead to advancements in technology and energy production.</p>

1. Could a Particle Accelerator Create a Black Hole That Destroys Earth?

No, it is highly unlikely that a particle accelerator could create a black hole large enough to destroy Earth. The energy levels produced by particle accelerators are much lower than those required to create a black hole. Additionally, any black holes created would be extremely small and would evaporate almost immediately due to Hawking radiation.

2. Is there any evidence that a particle accelerator could create a black hole?

No, there is no scientific evidence to suggest that a particle accelerator could create a black hole. Theoretical calculations and simulations have shown that the energy levels produced by particle accelerators are not high enough to create a black hole.

3. Could a black hole created by a particle accelerator grow and eventually destroy Earth?

No, even if a black hole were to be created by a particle accelerator, it would not be able to grow and destroy Earth. The Earth's gravity is not strong enough to be affected by a small black hole, and it would eventually evaporate due to Hawking radiation.

4. Are there any safety concerns regarding particle accelerators and black holes?

No, there are no safety concerns related to black holes and particle accelerators. As mentioned before, the energy levels produced by particle accelerators are not high enough to create a black hole, and any black holes that may be created would be too small and short-lived to pose any danger.

5. What are the potential benefits of studying black holes with particle accelerators?

Particle accelerators can provide valuable insights into the behavior of matter and energy in extreme conditions, such as those found in black holes. Studying black holes with particle accelerators can help us better understand the fundamental laws of physics and potentially lead to advancements in technology and energy production.

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