PBS Space Time

Is there a limit to how much energy you Is there a limit to how much energy you can cram into, or pull out of one patch of space?

Well, we thought so, but the James Webb Space Telescope has found a quasar that simultaneously breaks a century-old theoretical limit and may explain the conundrum of gigantic black holes in the early universe.

There are black holes at the beginning of time that dont make sense.

Theyre just too big.

Black holes grow by consuming matter and merging with other black holes, in some cases growing into the supermassive black holes in the centers of galaxies, intermittently powering enormously bright quasars in the process.

We see quasars as countless specks of light shining from the distant universe.

As weve learned to peer deeper and deeper into the cosmic dawn, we expected to see quasars dwindle in power.

Their black hole engines should be smaller the closer we get to the Big Bang.

But weve now found quite a few quasars from the first billion years that are way too massive to have grown by the mechanisms that we think we understand.

The James Webb Space Telescope is only finding more, and were forced to rethink our understanding of black hole formation and growth.

There are two broad ways to do this: either black holes started out uncomfortably large from colossal early stars and then fed almost continuously for a billion years, OR black holes managed to consume material much, much faster than we thought possible.

Although Webb is finding uncomfortably massive early black holes, its also finding clues to answering the conundrum.

Take a look at this guy LID-568, an active galactic nucleus recently observed with the Webb.

Its not the most massive black hole, nor is it the earliest at 1.5 billion years after the Big Bang.

Weve found quasars hosting black holes a thousand times more massive when the universe was half that age.

But LID-568 is special because its currently growing 4000 times faster than the theoretical limit.

Weve seen super-eddington accretors before, but nothing like this.

If LID-568s earlier, bigger siblings did the same thing then we may be closer to understanding how they got so chonky so fast.

But first we need to actually believe that this black hole really is feeding as fast as it seems to be.

Today I want to talk about the absolute limits of growth and power in our universe.

Whats the most energy you can both cram into and get out of a patch of space?

The physics were going to explore will describe the most extreme environments around the most massive black holes in the universe, but its also the same physics that first allowed us to understand something even more important: every star in the universe.

We tend to think of black holes as purely sucking.

They drag stuff in and spit nothing out.

But actually, as evidenced by the quasar, black holesor at least the regions around them-can be the brightest things in the universe.

As matter falls towards a black hole it heats up and radiates before dropping past the event horizonthe surface of no return.

That radiation can blast back other infalling material, shutting off the fueling of the black hole.

The theoretical limit to the rate at which a black hole can feed is called the Eddington limitits an upper bound on both the rate of fueling and power output in radiationalso called the luminosity.

At the Eddington limit the pressure from the outgoing radiation exactly balances the strength of gravity.

It seems like it should be impossible to feed a black hole any faster than the Eddington limit, or for a quasar to glow brighter than the Eddington luminosity.

LID-568 glows 4000 times brighter than this, and likely grows at a similarly super-Eddington rate.

The best way to understand how this is possible is to understand the origin of the Eddington limit.

Its named after this guy.

Now, when a science concept gets named after someone, sometimes they deserve credit, sometimes less so.

Sir Arthur Stanley Eddington and his limit are in the former category.

This dude was the OG astrophysicist.

He was supposedly one of the few who understood Einsteins general theory of relativity when it first came out, and he led the expedition to measure the bending of light around the sun in the 1919 eclipse, providing the first verification of GRs predictions.

Eddington correctly guessed that the source of energy in stars is the fusion of hydrogen into helium, and that was before we even knew that stars are made of hydrogen.

He pretty much founded the field of stellar physics, and this is where his eponymous limit actually comes from.

That means to understand quasars at their limit we also need to understand the limits of stars.

Eddingtons reasoning went like this.

Stars are massive, therefore have very powerful gravitational fields.

Powerful enough to cause any fluid such as a cloud of gas to collapse under its own weight.

Unless, that is, theres some outward push to resist the collapse.

Stars are not typically collapsing, therefore something must support them.

In Eddingtons time, a leading idea was that stars were hot from the energy gained by the gas as it collapsed to form the star.

For a gas, high temperature means high pressure, and that pressure resists further collapse.

Of course, stars radiate their internal energy, so this support has to diminish over time.

You might think that would leech away support and so cause the star to collapseat least a little bit.

But remember that collapsing converts gravitational potential energy into heat.

So as a star radiates energy it should also shrink and so generate more heat energy to resist collapse.

The result would be a very slow shrinking of the star.

In fact, this balance between gravity and gas pressure IS what keeps stars supported and stable.

But Eddington realised that such a star couldnt last nearly long enoughit would need another source of energyand, as I mentioned, Eddington guessed it must be fusion.

Eddington used this balance between gas pressure and gravity to figure out how the brightness of stars must depend on mass.

As mass increases, higher pressures and temperatures are needed to support against the increasing gravity, and higher temperature leads to higher luminosity.

Hotter things glow brighter.

A lot brighter.

Eddington calculated that the luminosity of a star acting as a pure ideal gas should increase with the cube of the mass.

In reality, things are a bit more complicated and the dependency can go as high as mass to the power of four and a half.

This is our first figuring out how luminous something can be.

Stars for now, but this stuff will extend to quasars.

Imagine adding mass incrementally to the Sun.

It grows rapidly brighter as you dolets say as mass to the power of three.

So double its mass and its 8 times brighter.

At 10 times its old mass its 1000 times brighter.

But theres a limit.

At some pointaround 55 times its current mass, a radical shift happens.

Eddington realised that gas pressure isnt the only thing that can support a star from collapse.

Gas pressure comes from particles bumping into each othertypically via electromagnetic interactions.

Try to compress a gas and the bumping increases, resisting the compression.

That direct bumping is mediated by the electromagnetic fieldwe could say via virtual photons.

But there are also real photons.

Any hot material is suffused with photons whose energy depends on the energy of motion of the particles.

Those photons also bump into the charged particles in the gas, and so they provide their own pressure.

We call this radiation pressure.

In stars, most of the radiation pressure comes from photons bouncing off electronsan interaction called Thomson scattering.

For most stars, this radiation pressure is tiny compared to gas pressure throughout the interiors.

But for the highest mass stars, the radiation pressure starts to dominate.

If we go back to addingmass to the Sun, once we get to 55-ish solar masses its radiating at several hundred thousand times its current level.

Now its supported almost entirely by the insane outflow of radiation.

Its now at the Eddington limit.

Adding more mass would still make it brighter, but not nearly so quicklynow brightness increases linearly with mass.

Were also at the upper limit of mass for stars found at least in the modern universe.

So Eddington figured all of this out for stars, but everything I just described also applies to black holes and quasars.

In a quasar we have mostly-hydrogen gas falling into a deep gravitational well, resisted by the energy generated in the center.

Now that energy comes entirely from converting gravitational potential energy into heat with no internal fusion, but the same battle between gravity and pressure applies.

Theres an obvious thing we can do to release all of that radiation so that it doesnt resist gravity.

Eddingtons assumption of a roughly spherical distribution of matter falling made sense for stars, but not for quasars, nor for most collapsing gaseous systemsinstead they form disks.

Weve discussed previously why disks are so commonfrom planetary rings to protoplanetary disks to spiral galaxies.

The main process driving this is conservation of angular momentum.

Any tiny rotation in the pre-collapse gas will be amplified as the cloud shrinks.

That same rotation will stop the material collapsing further along one plane, while the stuff above and below that plane will continue to collapsenow falling onto the increasingly massive disk of particles in orbit around the central mass.

In the case of black holes, this is an accretion disk.

The accreted material now orbits the black hole instead of falling straight in.

All orbits are filled, and because adjacent orbits have different orbital speeds they sort of rub against each other.

This is called viscous heating, and inside the disk its the process by which gravitational potential energy is converted into thermal energy.

But now, that thermal energy isnt trapped in the material and swallowed by the black hole.

The surface of the disk is exposed to space, and energy radiates from that surface.

The first fully self-consistent description of such an accretion disk came in the early 70s by the astrophysicists Nikolai Shakura and Rashid Sunyaev, and has been the standard model of such disks ever since.

The model describes a disk thats very thin, which means its easy for radiation to escape and the disk to become very luminous.

You might think that escaping radiation would make it easier for the black hole to feedafter all, if the radiation escapes then its not producing radiation pressure to resist gravity.

But actually, these thin disks are among the worst at feeding black holes.

Orbiting things dont fall into the things theyre orbitingas evidenced by the fact that our planet doesnt just drop into the Sun right now.

In order for the black hole to gobble the material of the disk, that material needs to lose its angular momentum.

The friction and turbulence between adjacent orbits will do that, but very inefficiently.

The result is that these thin disks are luminous but feed the black hole at way less than the Eddington rate.

The resistance to in fall due to angular momentum is so strong that to break the limit on feeding our black hole, were better off if our accretion disk looks a little more like the stars that we started this episode with.

Imagine we have a quasar with a classic thin accretion disk.

We start feeding more mass into the disk, like we did for the Sun.

More material means more fuel for heating the disk.

At some point, theres so much thermal radiation in the hottest part of the disk near the center that radiation pressure puffs up the inner disk.

It becomes then harder for that radiation to immediately escape the disk.

Now we have a disk supported by radiation pressure more than angular momentum, with gas pressure also playing a role.

Because angular momentum is no longer as important, it becomes easier to drain the disk into the black hole.

But we still have the problem we started with: radiation pressure and our original Eddington limit.

Overcoming this limit is now possible because the accretion flow remains at least somewhat disky, rather than being an encompassing sphere like in a star.

Radiation bouncing around in the disk is transported inwards with the infalling plasma in a process called advection, and eventually it encounters the inner opening of the disk where its able to escape.

The disk radiation gets channelled or collimated upwards and downwards in these central cones that can be enormously bright if you see them from the right direction.

Meanwhile, the material of the disk, now relieved of some of the radiation pressure, is able to complete its infall into the black hole.

These thick accretion disks come in various typestheres the Polish doughnut where the whole disk is thick, almost spherical besides the central funnels.

Or the slim disk in which just the middle, hottest part puffs up.

All of them are capable of super-eddington accretion rates, and also super-eddington luminosities, and this has been demonstrated with modern computer simulations.

The downside is that these thicker accretion disks produce less energy for each chunk of matter swallowed by the black holebut the shear amount of matter consumed can make up for that.

So theres a good chance that this is exactly whats happening in cases like LID-568.

This isn't the only super-Eddington active galactic nucleus we've ever seen but it's one of the most extreme.

And now that weve seen this sort of extreme-super-Eddington accretion in the early universe like it's evidence that this sort of accretion is crucial for the rapid growth of early black holes.

I mentioned that the alternative explanation for that rapid growth is that early black holes grew via sub-Eddington accretion at an almost constant rate after already starting out with a massive seedand this an idea that strains plausibility.

But if blackholes can go through these extreme growth phases, even if only briefly, then it becomes a lot easier to build a very massive black hole in the early universe, at least given our current understanding of what that epoch was like.

No doubt if extreme accretion is the answer to our conundrum then the James Webb Space Telescope will find more objects like LID-568the fast growing black holes that ultimately power the brightest quasars to shine from the dawn of spacetime.