Astrophysicists Find No &#x27;hair&#x27; on Black Holes

https://www.wikipedia.org/wiki/List_of_unusual_biological_na...

4 months ago

Does the Hairy Ball theorem apply to hairless black holes?

Asking for a friend...

jleyank

4 months ago

1 reply

If they finds "casual" names for scientific principles annoying, they're going to just LOVE the names for genes. hERG activity is a bad thing that gets drugs taken off the market (cardiac arrhythmia). hERG means "human ether-a-go-go-related gene". Scientists are human, and obviously playful at times.

It's not a recent thing. Check out quark names and their associated properties.

kgwgk

4 months ago

A few examples:

https://en.wikipedia.org/wiki/List_of_chemical_compounds_wit...

mr_mitm

4 months ago

This is the first time I heard quanta magazine being accused of click bait. They show no ads and don't sell anything. What would be their motivation for using click bait?

Click bait used to mean things like "five reasons you always get sick - number three will SHOCK you" or "doctors hate this one weird trick!".

The title of this article isn't click bait at all. Black holes having hair or not is almost the technical expression, as evidenced by the "no hair" theorem. Physicists are quirky like that sometimes.

ordu

4 months ago

Yeah. The photo of a hairy astrophysicist claiming that if black holes have hair, it is shorter than 40 km seems like a petty way to spark a public interest.

xeonmc

4 months ago

6 replies

    The question of hairy black holes is intimately connected to the greatest puzzle in modern physics: How can general relativity be merged with quantum theory?
    
    Consider the situation where an object crosses a black hole’s point of no return, called the event horizon. According to general relativity, all outsiders will see is how the swallowed object contributes to the two numbers that describe the black hole: how much mass the object adds, and how much faster or slower it makes the black hole rotate.

The idea that anything within the event horizon should be treated as an opaque black box -- could it be reinterpreted as saying that any property which has dependence on spatial or temporal distribution within becomes an unknowable quantity? If so, can it be tied somehow to Quantum Mechanic’s idea of the removal of degrees of freedom by observation, since now certain quantities are not unobserved but rather unobservable in principle? I am asking this from a naive laymen’s point of view, so I may be conflating entirely unrelated ideas.

layer8

4 months ago

1 reply

For one, observers inside the event horizon can still observe each other. From the point of view of an observer falling into a black hole, nothing unusual happens when they cross the event horizon. They still observe stuff falling in with them in the same way as before (assuming a large enough black hole so that the local curvature is negligible).

If Hawking radiation is real, it might also expose information from inside the black hole, possibly solving the information paradox. In that sense, the inside of a black hole would still be “observable” from the outside in the QM sense. But since we don’t know how quantum gravity works, that is an open question.

agent327

4 months ago

1 reply

How can that be true? Inside the event horizon, there is only one direction: down. If light cannot escape, how can it happily bounce around, reflect on something, then reach your eyes? How could signals from your feet (say) even reach your brain, assuming a feet-first entry into the black hole?

layer8

4 months ago

1 reply

When you cross the event horizon, you’re falling at close to the speed of light, relative to the event horizon. But due to relativity, light bouncing off the falling objects still propagates at light speed in all directions relative to the falling objects (including the falling observer). That light can’t move outwards, due to being inside the event horizon, and accelerates towards the singularity, but the observer accelerates to the singularity faster, relative to light being reflected outwards. The falling rest frame accelerates towards the singularity, but within that accelerating rest frame, light behaves normally between objects in that frame (assuming a large enough black hole so that the differences in radial distance between the objects is negligible).

Consider two cars driving on a highway at the same speed. If one of the cars decelerates, it appears to be moving backwards relative to the other car, while still continuing to move forward relative to the road. It’s similar for light and an observer falling towards the singularity. They both fall towards the singularity, but light being reflected backwards will fall a bit slower, thus appearing to move backwards relative to the observer, even though the light still moves forward toward the singularity.

thunderbong

4 months ago

Very well explained. Thank you

Arwill

4 months ago

I think what is relevant here, is that there is a separation between the inside and the outside of the black hole. Since there is no communication between the two, on the inside it could be anything. And its not just the matter and space, even the laws of physics might be completely different. If it weren't so, then there had to be a "super-space" that communicates how ordinary space behaves on both the outside and the inside the black hole.

anuramat

4 months ago

with QM, the "unobservable" stuff is just guaranteed to not be there, eg a particle detected at (x,t) is definitely not at (x',t); so you are observing it "not existing there" -- collapse just makes the measurement at (x',t) redundant

meanwhile with black holes you know there is something, but you can't measure

in both cases you don't get any information, but in QM it's only because you already know everything there is to know about the system

could it end up being fundamentally the same thing? I don't see why not, but for it to make sense you'd have to get a nobel prize for grand unification theory first

also, collapse is not real and can't hurt you anyway, see many-worlds

trjordan

4 months ago

Not exactly. Black holes are not lopsided, for instance. There isn't anything on "one side" of them, once the matter has crossed the event horizon.

Rotating black holes are pretty well modeled as a spinning ring: https://en.wikipedia.org/wiki/Ring_singularity

4 months ago

I think the short answer is that no one knows, because a proper answer would need an understanding of how black holes and quantum theory go together, which is not currently known.

The longer answer (if you want to get in to the extensive literature) is that your question seems to relate to the black hole information paradox https://en.wikipedia.org/wiki/Black_hole_information_paradox

gus_massa

4 months ago

No. The "no hair theorem" has a condition that says "after a while", but people ignore it because it's a short time. So intermediately after the object entered the black hole will have bump and will emit gravitational waves and after a while it will be a perfect sphere (if it's not rotating, or a similar round elongated shape if rotating).

As far as I can understand, it totally unrelated to Quantum Mechanics.

datadrivenangel

4 months ago

1 reply

Another blow against string theory.

importantstuff

4 months ago

1 reply

You might want to consider the article more carefully, especially the section "Short Hair, Long Hair". The predictions of string theory are in no way falsified by the analysis conducted by these researchers.

4 months ago

In fact, it's hard to find predictions of string theory that are falsifiable at all.

4 months ago

1 reply

An interesting consequence of having "no hair" on them is that information on everything that falls in them is lost forever, which leads us to an information loss paradox. Not nice.

fpoling

4 months ago

1 reply

You do not need a black hole for the information loss. Just shout a flashlight into empty space. Any information encoded in photons will be lost from the point of view of the sender.

And then the classical notions like information or entropy are not really compatible with General Relativity. Richard Tolman almost 100 years ago proposed interesting extension to the classical thermodynamics that is compatible and can potentially explain apparent paradox of information loss, but it is not known if that extension matches reality.

4 months ago

1 reply

> Any information encoded in photons will be lost from the point of view of the sender.

The crucial difference is "from the point of view of the sender". The black hole information paradox is that the information is lost from any possible receiver (even any possible ensemble of receivers surrounding the black hole). It's not the same thing

fpoling

4 months ago

2 replies

The information is not lost from the point of view of receivers inside the black hole horizon.

Which again points out that the classical notion of information just does not work in a universe with multiple causally disconnected regions.

4 months ago

1 reply

What happens when the black hole evaporates then, and there is no more horizon? That's the black hole information paradox

butlike

4 months ago

Single point of ~infinite charge?

4 months ago

1 reply

>The information is not lost from the point of view of receivers inside the black hole horizon.

Information is lost beyond the event horizon. There is no such thing as "point of view of receivers inside that black hole", everything collapses into a single point or some dimensionless thing or whatever. That's why it is called a singularity.

4 months ago

1 reply

I do not know of any theories that agree with this. In fact, most admit that "you wouldn't even notice (if somehow still alive) when you crossed the event horizon" - because the only thing that happens is the photons you emit go from taking billions of years to escape, to never escaping.

And that's not why it's called a singularity. It is NOT a single point, nor dimensionless. It has a well-defined dimensional size, the Schwarzwald Radius.

4 months ago

1 reply

>I do not know of any theories that agree with this.

It shows.

You confuse "dimension" with "magnitude", for starters.

4 months ago

1 reply

> It shows.

Why be so extravagantly supercilious on the internet?

It's ironic because it seems you're not that familiar with general relativity, and confuse the entire region within the event horizon with the singularity.

Black holes have a causally connected region within the event horizon which is distinct from the singularity, so there can in fact be observers within the event horizon that are in communication with each other, and they can have a perspective, i.e. receive information. The simplest black hole model would be the Schwarzschild black hole (a static, spherically symmetric spacetime, which is empty apart from the central mass) with the Kruskal-Szekeres coordinates, which smoothly continue over the event horizon.

Here's a nice discussion by John Baez about what you might see as you cross the event horizon: https://johncarlosbaez.wordpress.com/2024/11/30/black-hole-p...

To some extent though, what really happens within the event horizon remains speculative, because we can't directly verify any of these predictions about what happens there without actually crossing the horizon ("What happens within the event horizon, stays within the event horizon"). We just make inferences based on the structure of our currently most predictive theory for gravitational phenomena outside event horizons (which is general relativity, ofc)

4 months ago

1 reply

>and confuse the entire region within the event horizon with the singularity.

Can you point out where? I'm always open to learn.

Btw, I don't read Baez as I consider him trash.

4 months ago

> Can you point out where?

Here:

> Information is lost beyond the event horizon. There is no such thing as "point of view of receivers inside that black hole", everything collapses into a single point or some dimensionless thing or whatever. That's why it is called a singularity.

I'd say you're missing out by not reading Baez. He's an extremely gifted thinker and communicator. He knows his stuff

alex1138

4 months ago

1 reply

Black hole goes into a barbershop

Barber goes "You're kidding me, right?"

slipperydippery

4 months ago

1 reply

Black hole goes into a barbershop.

Barber goes, "You're kiddiinnngggg mmmmmmeeeeeeeeee, riiiiiiiiiiiiiiiiiiiiiiiiiiiiiii...."

* https://youtube.com/watch?v=zPZrDbPAuKs

4 months ago

The bartender says "We don't serve Tachyons here."

A Tachyon walks into a bar.

FergusArgyll

4 months ago

3 replies

This reminds me of something I mull over; Greek style philosophy seems so smart, rational and correct until you actually observe the world. Imo the perfect example is elementary particles - the Greeks (mostly) were convinced that it's impossible for something physical to be elementary (cannot be further split) and logically it is hard to understand why can't we continue to split the particle?! but hey, we can't.

Physical beings which cannot be distinguished from one another would have made their heads spin...

wahern

4 months ago

1 reply

Aren't quarks and, probably, electrons point-like particles? In that sense the fundamental subatomic particles aren't "physical" in the sense the Greeks would have thought of them, e.g. having a non-0 diameter, and in that way modern physics sort of vindicates their deductive reasoning. Their logic wasn't wrong, per se, it was their starting assumptions that were flawed (or at least incomplete), which is acceptable as far as deductive reasoning goes.

JdeBP

4 months ago

No. Because the GR/QM conflict comes up in the other direction that way. GR predicts infinities for zero-radius particles. Indeed, so too does classical electromagnetism. In any case, "quanta" does not really mean the same as the classical notion of point particles.

JdeBP

4 months ago

Indeed. That's rotational frame dragging for you. (-: