Black Holes Could Turn You Into a Hologram, and You Wouldn’t Even Notice
An illustration of a black hole. Despite how dark it is, all black holes are thought to have formed from normal matter, not dark matter. Image credit: NASA/JPL-Caltech.
Dark matter is the most abundant form of mass in our Universe. If you were to add up all the stars, planets, lifeforms, gas, dust, plasma and more — all the known, “normal” matter in our Universe — it would only account for about 15-to-17% of the total gravitation that we see. The remaining mass, outclassing the normal matter by a 5:1 ratio, must be completely invisible, meaning it doesn’t absorb or emit light at all. Yet it must interact gravitationally, enabling it to form large-scale structure in the Universe and to hold galaxies together. So why, then, can’t it form black holes?
Black holes aren’t the only thing dark matter can’t form; it also can’t create dark matter stars, planets or dark atoms. Imagine the Universe as it might have been back in the very, very early stages, before there were any black holes, stars, planets or atoms.
The early Universe was full of matter and radiation, and was so hot and dense that the quarks and gluons present didn’t form into individual protons and neutrons, but remained in a quark-gluon plasma. (Image credit: RHIC collaboration, Brookhaven, via http://www.bnl.gov/newsroom/news.php?a=11403)
All we had was a hot, dense, expanding “sea” of matter and radiation of all the different types allowed. By time the Universe has aged to be a few minutes old, the atomic nuclei are there, all the electrons are there, all the neutrinos and photons are there, and all the dark matter is there, too.
They’re all flying around at incredible speeds, sure, but they’re also all exerting forces on one another. It’s true that they all feel the gravitational force (even photons, thanks to Einstein’s energy-mass equivalence), but gravity isn’t the only thing that matters here.
In the hot, early Universe, prior to the formation of neutral atoms, photons scatter off of electrons (and to a lesser extent, protons) at a very high rate, transferring momentum when they do. (Images credit: Amanda Yoho)
hotons and electrons have it the worst: they interact very frequently through the electromagnetic force, scattering and “bouncing” off of one another, exchanging energy, momentum and colliding at an alarming rate. Nuclei fare only a little better: they’re much more massive, so their interaction rate is lower, and they pick up (or lose) less momentum with each collision.
Neutrinos are much luckier: they don’t have an electric charge, and so they don’t interact through the electromagnetic force at all. Instead, they can only interact (besides gravity) through the weak force, which means collisions are incredibly infrequent. But dark matter gets it the best in terms of freedom: as far as we can tell, it only interacts through gravity. There are no collisions at all, and so all dark matter can do is be attracted to the other sources of matter.
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This might, you worry, make things worse! While normal matter has collisions and interactions preventing it from collapsing gravitationally, forming denser clumps, etc., the dark matter density begins to grow in the overdense regions. But this doesn’t happen the way you think of “collapse” happening. When a gas cloud collapses to form stars, what happens?
A massive, gaseous nebula is where new stars in the Universe are born. (Image credit: ESO/VPHAS+ team, via http://www.eso.org/public/images/eso1403a/)
The gas interacts through the gravitational force, becoming denser, but the matter that makes up that gas sticks together, allowing it to reach a denser state. That “stickiness” only happens thanks to the electromagnetic force! This is why things can collapse down to produce bound objects like stars, planets and even atoms.
Without that stickiness? You’d just end up with a diffuse, loosely held together, “fluffy” structure bound together only through gravity. That’s why you hear of dark matter halos on galaxy and cluster scales, of dark matter filaments on even larger scales, and of no other dark matter structures.
Now, these diffuse, fluffy halos are incredibly important: they represent the seeds of all the bound structure in the Universe today. This includes dwarf galaxies, normal galaxies, galaxy groups, galaxy clusters, superclusters and filaments, as well as all the substructure that makes these objects up. But without that extra force — without some “sticky” force to hold it together, to exchange energy and momentum — the dark matter is destined to remain in this fluffy, diffuse state. The normal matter can form the tightly-bound structures you’re used to, but the dark matter has no way to collide inelastically, to lose momentum or angular momentum, and hence, it has to remain loosely bound and “halo-like.”
While stars might cluster in the disk and the normal matter might be restricted to a nearby region around the stars, dark matter extends in a halo more than 10 times the extent of the luminous portion. (Image credit: ESO/L. Calçada)
It’s a little disconcerting to think that it’s not the gravitational force that leads to planets, stars, black holes and more, but gravity is just part of the equation. To really drive this point home, imagine that you took a ball of some type and launched it, with the ball — as you know — made out of atoms. What’s the ball going to do?
A projectile under the influence of gravity will move in a parabola, until it strikes other matter (like the floor) that prevents it from moving further. (Image credit: Wikimedia Commons users MichaelMaggs Edit by Richard Bartz under c.c.a.-s.a.-3.0)
Of course, it’ll move in a parabolic path (neglecting air resistance), rising up to a maximum height and falling down until it finally strikes the Earth. On a more fundamental scale, the ball moves in an elliptical orbit with the center-of-mass of the Earth as one focus of the ellipse, but the ground gets in the way of that ellipse, and so the portion we see looks like a parabola. But if you magically turned that ball into a clump of dark matter, what you’d get would surprise you greatly.
Normal matter is stopped by the Earth, but dark matter would pass right through, making a near-perfect ellipse. (Image credit: Dave Goldberg of Ask A Mathematician/Ask A Physicist, via http://www.askamathematician.com/2012/01/q-why-does-gravity-make-some-things-orbit-and-some-things-fall/)
Without the electromagnetic force, a whole bunch of terrible things happen:
There’s no interaction, other than gravity, between the particles making up the ball and the atoms of the Earth. Instead of making a parabola, the dark matter clump goes all the way through the layers of the Earth, swinging around the center in an (almost-perfect) ellipse (but not quite, due to the layers and non-uniform density of the Earth), coming out near where it entered, making a parabola again and continue to orbit like that interminably.
There are also no interactions holding this clump together! So while atoms in a ball do have some random motions, they are held together by the electromagnetic force, keeping that ball-like structure to it. But if you remove that electromagnetic force, the random motions of the dark matter particles will work to unbind this from being a clump, since the gravitation of the clump itself is insufficient to keep it bound together.
This means that over time (and many orbits), the dark matter gets stretched into a long ellipse, and that ellipse gets more and more diffuse, similar to the particles that make up the debris stream from a comet, only even more diffuse!
(Image credit: Gehrz, R. D., Reach, W. T., Woodward, C. E., and Kelley, M. S., 2006, of the trail of Comet Encke)
Dark matter can’t form black holes or other tightly-bound structures because gravity alone isn’t enough to bind something tightly together. Because the force of gravity is so weak, it can only bind it loosely, which means huge, diffuse, very massive structures. If you want a “clump” of something — a star, a planet, or even an atom — you need a force that’s stronger than gravity to make it happen.
There may yet be one! It is possible that dark matter self-interacts (or interacts with matter or radiation, at some level), but if it does, we only have constraints on how weak that interaction is. And it is very, very weak, if it’s even non-zero at all.
If dark matter does have a self-interaction, its cross-section is tremendously low, as direct detection experiments have shown. (Image credit: Mirabolfathi, Nader arXiv:1308.0044 [astro-ph.IM], via https://inspirehep.net/record/1245953/plots)
So even though we think of gravity as the only force that matters on the largest scales, the truth is when we think about the structures that we see — the ones that give off light, that house atoms and molecules, that collapse into black holes — it’s the other forces, in concert with gravity, that allow them to exist at all. You need some type of inelastic, sticky collision, and dark matter doesn’t have the right interactions to make that possible. Because of that, dark matter can’t make a galaxy, a star, a planet or a black hole. It takes more than gravity alone to do the job.
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“Starts With A Bang! is a blog/video blog about cosmology, physics, astronomy, and anything else I find interesting enough to write about. I am a firm believer that the highest good in life is learning, and the greatest evil is willful ignorance. The goal of everything on this site is to help inform you about our world, how we came to be here, and to understand how it all works. As I write these pages for you, I hope to not only explain to you what we know, think, and believe, but how we know it, and why we draw the conclusions we do. It is my hope that you find this interesting, informative, and accessible,” says Ethan