Astronomers Discover Link Between Supermassive Black Holes and Galaxy Formation

Feb 02, 2009
Astronomers Discover Link Between Supermassive Black Holes and Galaxy Formation
Two giant elliptical galaxies, NGC 4621 and NGC 4472, look similar from a distance, as seen on the right in images from the Sloan Digital Sky Survey. But zooming into these galaxies' cores with Hubble Space Telescope reveals their differences (left, black and white images). NGC 4621 shows a bright core, while NGC 4472 is much dimmer. The core of this galaxy is populated with fewer stars. Many stars have been slung out of the core when the galaxy collided and merged with another. Their two supermassive black holes orbited each other, and their great gravity sent stars careening out of the galaxy's core. Credit: NASA/AURA/STScI and WikiSky/SDSS

(PhysOrg.com) -- A pair of astronomers from Texas and Germany have used a telescope at The University of Texas at Austin's McDonald Observatory together with Hubble Space Telescope and many other telescopes around the world to uncover new evidence that the largest, most massive galaxies in the universe and the supermassive black holes at their hearts grew together over time.

"They evolved in lockstep," said The University of Texas at Austin's John Kormendy, who co-authored the research with Ralf Bender of Germany's Max-Planck-Institute for Extraterrestrial Physics and Ludwig Maximilians University Observatory. The results are puiblished in this week's issue of Astrophysical Journal Letters.

Astronomers know that galaxies, those vast cities of millions or billions of stars, grow larger through collisions and mergers. Kormendy and Bender's work involves the biggest galaxies in the universe--"elliptical galaxies" that are shaped roughly like footballs and that can be made of as many as a thousand billion stars. Virtually all of these galaxies contain a black hole at their centers, that is, an infinitely dense region that contains the mass of millions or billions of Suns and from which no light can escape.

A current leading theory says that when galaxies collide, their black holes end up revolving around each other. Together, the two black holes act like an egg beater: They violently stir up the galaxy center with their incredibly strong gravity, and they fling stars out of the central regions. As the black hole pair sinks to the center of the new merger remnant, this supergalaxy's core is depleted of the stars that were flung away. Kormendy and Bender measured the resulting dimming of such galaxies' cores, their so-called "light deficits."

Light deficits in galaxy cores are surprising in view of decades of work by many astronomers, including Kormendy and Bender, which showed that the biggest elliptical galaxies contain the most massive black holes at their centers. These are monsters "weighing in" at a billion or more times the mass of our Sun. They attract the stars around them with ferociously strong gravity. Astronomers expected that such big black hole would yank the galaxy's stars into a tiny, dense cluster at the center. But observations in the 1980s with ground-based telescopes and much better observations in the 1990s with Hubble Space Telescope revealed the opposite. The biggest galaxies have big, fluffy, low-density centers. Why are giant black holes not surrounded by dense cluster of stars? Where did the missing stars go?

The theory that black hole binaries gravitationally slingshot the stars out of galactic centers has been the popular but unproved explanation. No telescope observations provided compelling evidence--until now.

"Our new observations are a strong and direct link between black holes and galaxy central properties," Kormendy says. "They are a 'smoking gun' that connects black holes with the formation of the surprisingly fluffy centers of giant elliptical galaxies."

Kormendy and Bender made detailed studies of 11 such galaxies in the Virgo Cluster. To get a comprehensive overall picture of each galaxy, they used the wide field of view of the Prime Focus Camera on McDonald Observatory's 0.8-meter Telescope. They used Hubble Space Telescope to study these same galaxies' cores in great detail. Many other telescopes were used to connect the central data from Hubble with the outer data from the McDonald telescope. The results on 27 elliptical galaxies in the Virgo Cluster measured by Kormendy, Bender, and their University of Texas colleagues David Fisher and Mark Cornell, and supported by the National Science Foundation, are scheduled for publication in a forthcoming issue of the Astrophysical Journal Supplement Series.

Their precision measurements of the brightnesses--that is, the number of stars--at various distances from the centers of elliptical galaxies allowed them to calculate much more accurately than previously the masses of stars that are "missing" in the centers of the biggest ellipticals. This revealed more surprises: The missing mass increases in lockstep with the measured masses of the central black holes. It was known that the two quantities are related, but it was not known that the correlation is so tight as to be within the margin of error. That is, the correlation is virtually perfect.

The missing mass also increases in lockstep with another galaxy property that is known to be tied directly to black holes, namely the speeds at which stars move far out in the galaxy where they cannot feel the black hole's gravity.

"Astronomers love tight correlations," Bender says. "They tell us what is connected with what. The new observations give us much stronger evidence that black holes control galaxy formation, at least at their centers."

According to Linda Sparke, NSF program director for astronomical sciences, "This valuable research shows how black holes grow along with the galaxy. This is big news. We've long accepted that black holes are not scattered randomly in galaxies. The most luminous galaxies harbor the most massive black holes. But we haven't known just how the black hole and the galaxy influence each other. Kormendy and Bender have seen the footprint of merging pairs of black holes in the centers of huge elliptical galaxies, revealing evidence that the largest black holes form after smaller galaxies collide to produce one larger system."

Kormendy finally adds, "We have long believed that black holes power quasars in galactic nuclei--they are the brightest objects in the universe. And we have come to suspect that putting giant black holes at the centers of young galaxies and shining so much quasar light on them affects galaxy formation. In other words, we suspect that the study of quasars and the study of galaxies are really one subject. We can't understand one without understanding the other.

"We think we have helped to merge these subjects by connecting black holes directly to galaxy structure." he said. "John Muir famously said that everything is hitched to everything else in the world. As we find that different subjects are hitched together, we build a theory of galaxy formation that we confidently believe."

Provided by National Science Foundation

Explore further: Lucky star escapes black hole with minor damage

add to favorites email to friend print save as pdf

Related Stories

NASA Webb's heart survives deep freeze test

5 hours ago

After 116 days of being subjected to extremely frigid temperatures like that in space, the heart of the James Webb Space Telescope, the Integrated Science Instrument Module (ISIM) and its sensitive instruments, ...

Recommended for you

Image: Galactic wheel of life shines in infrared

15 hours ago

It might look like a spoked wheel or even a "Chakram" weapon wielded by warriors like "Xena," from the fictional TV show, but this ringed galaxy is actually a vast place of stellar life. A newly released ...

New window on the early Universe

Oct 22, 2014

Scientists at the Universities of Bonn and Cardiff see good times approaching for astrophysicists after hatching a new observational strategy to distill detailed information from galaxies at the edge of ...

User comments : 20

Adjust slider to filter visible comments by rank

Display comments: newest first

mysticshakra
1.7 / 5 (6) Feb 02, 2009
In order to prove a link between black holes and galaxy formation it would require proving that black holes exist in the first place.

Oh wait, astronomy stopped requiring proof for it's religious ideas a long time ago.

Experimental/observational data? Who needs it.
LuckyBrandon
3.8 / 5 (4) Feb 02, 2009
actually and factually, the existence of black holes is very well known. what is not known, is what makes them, and what they actually comprise of.
denying their existence is simply idotic, on an extreme scale, but we need more data to figure out what they actually are.
how many black holes need to be seen and measured before stupid comments like the above go away??
axemaster
4.3 / 5 (4) Feb 02, 2009
Well, in fairness to mysticshakra, we have never directly observed a black hole. By directly observe, I mean measure closely enough to be absolutely certain that they cannot be some sort of near-black-hole-density mass (some other sort of ultra high density material, but not quite black hole)

That will hopefully change when the LHC is fixed and running again, since it has the potential to generate black holes that we could directly measure.

All of this aside, I DO take considerable objection to you saying that astronomy is "religious". Very insulting notion - you're probably the religious one.
denijane
3 / 5 (2) Feb 03, 2009
Black holes may very well not exist. There will be much more to say about them in the near future.
And check this article for more info about the need and the actuality of the black holes. http://www.arxiv....901.4365
theophys
4 / 5 (1) Feb 03, 2009
We should probably make a clear list of things that have been observed, things that are predicted but unobserved, and things that have been proven false through observation. We could hand it out along with the 2010 census and hopefully eliminate idiotic remarks arguing against the existence of observed phenomena.
OckhamsRazor
5 / 5 (1) Feb 03, 2009
That's ok, "mysticshakra", because by the same notion you don't exist to us either. We've observed the effects of your existence (the gibberish drooled onto this page by yourself) but we haven't seen nor been able to predict where it came from and what caused it. You're just someone else's "religious idea". There is far more proof and evidence of a black hole's existence than there is for your own.
earls
1 / 5 (1) Feb 04, 2009
Well then, please theophys, OckhamsRazor, enlighten us to all of the massive amounts of evidence for the current definition and understanding of the "areas" referred to as "black holes."

To the best of my knowledge, the only evidence available is matter or stars whipping wildly around a dark central point.

Is there even any gravity lensing evidence?

Even more perplexing to the whole situation is that "black holes" produce bipolar jets (sometimes happy, sometimes angry...)

Direct from NASA, they have no idea what's going on...

http://imagine.gs...23a.html

"thought to generate tangled-up magnetic field, which is probably what collimates the jets. However, astrophysicists are still working out the details of how material is lifted up from the accretion disk in the first place, and how exactly it is that the accelerating force (probably radiation pressure) can overcome the gravity of the central object."

Wowza!
denijane
not rated yet Feb 04, 2009
If you did read the link I gave you, you'll know that there are ways to mimic a black hole.
The actual proof of a black hole would involve observing an event horizon (or events that point to the existence of event horizon). Since all we see is accretion, then the existence of BH isn't proved. What's more, the data from the GRB shows a great inconsistency with the idea of BH as their progenitors. Which puts even bigger question on the existence of BH at all.

As fun as it is to solve differential equations, mathematics isn't physics. There might be black hole solutions, but how stable they are, how much they last and if they are what we observe in the galactic centres is another question. As for the moment, the only thing we know is that there is extremely heavy object in the centre. Only that.
mysticshakra
1 / 5 (2) Feb 05, 2009
theophys
not rated yet Feb 05, 2009
enlighten us to all of the massive amounts of evidence for the current definition and understanding of the "areas" referred to as "black holes."

To the best of my knowledge, the only evidence available is matter or stars whipping wildly around a dark central point.

Is there even any gravity lensing evidence?

there is no gravity lensing evidence that I know of for two reasons. 1) stellar black holes are ery small, so if they are in a binary system the lensing effects will basically be invisible and 2) Outside of a binary system, the star, black hole, and earth must all be aligned so perfectly that the odds of us actualy catching the effects are astronomical(haha, pun).
The first observations were in binary systems using a combination of x-ray observations and using the velocity of the visible star to calculate the mass of the smaller of the pair. If the x-rays and mass match prediction, we have a stellar black hole. Yay! Not infallible, but hey, nothing is.
There was a bunch more after the first discoveries to make certain, but i have no idea as to exactly what. Everything I've ever read just indicates that there was a good decade of calculations, expiriments, observations, ect. Also, I know they brought in a bunch more data when they started observing "radio galaxies." Later on they found massive black holes at the center of galaxies, yadda yadda, everyone knows the story. I don't know all the data, but I'm confident that thirty years of observation, calculation, and ensuing expiriments on earth have brought some modicum of certainty to the existence of black holes.
earls
1 / 5 (1) Feb 05, 2009
Well, I'm glad you're so easily persuaded and that no other options exist because hey, it has been "30 years!" ...of no progress, only increasing contradictions of theories that are allowed to exist for no other reason except to maintain the exotic, fanciful lore of an "an infinitely dense region that contains the mass of millions or billions of Suns and from which no light can escape."

And it's great, I get away with my ignorance and nay-saying because there is literally NO EVIDENCE to the contrary... Besides shit whipping wildly around a "central point."

Everything is inferred from Cavendish's experiment, "the universal gravitational constant."

A couple facts of which...

"The gravitational constant is perhaps the most difficult physical constant to measure."

"Another authoritative _estimate_"

"The accuracy of the measured value of G has increased only modestly since the original experiment of Cavendish."

"gravity has no established relation to other fundamental forces, so it does not appear possible to measure it indirectly."

"published values of G have varied rather broadly, and some recent measurements of high precision are, in fact, mutually exclusive."

Is that level of uncertainty about something so intricate really enough to say "this is the absolute truth of the situation?" Oh well ya know earls, it's 211 years old so I mean how could there be any doubt?!
LuckyBrandon
1 / 5 (1) Feb 09, 2009
we call them black holes imply because we cant see them directly in all the blackness of space other than their gravitation effects...but there has been a TON of progress on the examination of black holes. but no matter what the progress made is, a black hole in concept is really as simple as a whirlpool in water, ESPECIALLY if you view space-time as a fluid motion, there will be ripples, which in turn when combined can make whirpools, which in turn will cause mass to form around them and whip in there. the only difference really is that a whirlpool in water doesn't break things apart at a deep level as a black hole does. as far as the jets go...think of the theory that black holes connect to other parallel universes...in this context, our black holes with all the matter they suck up would have to excrete it from the other side, and vice versa. this of course would indicate a core of sorts that does allow things to come back up...i think core is the wrong word here though...maybe more of a hollow point, like on a funnel youd use to put oil into your car.
earls
1 / 5 (1) Feb 09, 2009
Brandon, that is absolute fantasy.
theophys
not rated yet Feb 12, 2009
Earls, you're using equations that were outdated a century ago. Black holes were derived from Einstein's equations. I don't belive there were any constants in those. I could be wrong.
Also, there is absolutely no counter theory to explain what we have seen. Black holes are the best we've got and no substansive holes have been poked in the theory. The math is all there to support them. I know denijane said earlier that "math is not physics" but that's not entirely right. Physics is just applied mathematics with expirimentation. Everything that has been done so far has screamed black hole in our faces.
If you have an alternative theory that is more complete, observable, and supported by mathematics, I would love to take a looksie.
LuckyBrandon
1 / 5 (1) Feb 15, 2009
earls-not if you look at it for what it is, a simplified explanation of the actual thought of a black hole. its not meant to be anything but that. a very simple explanation, that in fact, is not far and is not fantasy when looking at the dynics of what we think a black hole is truly doing.
it could turn out to be completely incorrect, of course, but there are valid scientific theories for it out there...and who knows, maybe your bubble there is the fantasy.
to beat a dead horse here, my little idea there was just to give a simply example of how soemthing could be flowing out of a black hole and escape the gravitational pull potentially....
earls
1 / 5 (1) Feb 15, 2009
Yes, parallel Universes are the "simple explanation."
Adriab
not rated yet Feb 18, 2009
Black holes are a consequence of physics equations that model experiments. That is, there are equations showing how matter, when densly packed, repells itself with what is called Neutron Degeneracy Pressure.

You can calculated a radius and mass at which gravity can overcome this pressure. When gravity is greater than pressure, collapse occurs. This is thought to be the cause of supernovae.

Now theory steps in and says the resultant object is a black hole, something super-dense, and quite small. Most other claims are conjecture.

Theory is needed to direct experiments. Experiments then prove a theory likely to be true, or false.

So we have a theory. That's a good thing. Only a theory? Well let's get to designing some experiments.
yep
1 / 5 (2) Feb 22, 2009
"scientific facts like black holes and the big bang are merely flawed mathematical constructs."
http://www.holosc...6bcdajsb
jeffsaunders
1 / 5 (1) Jun 05, 2009
I started off ready to agree with Earls above and I guess incidently with mysticshakra who started this thread off.

But once I started putting my argument down here I came to realise that there is a possabilty for a black hole to exist. That does not mean they do however, just that they may be possible even with the true picture of the universe.

Forget Big Bang hokus pokus and forget MOND and forget antigravity and space foam and forget gravity being an independent property of mass. Think of gravity being caused by a lack of pressure on one side rather than a mysterious force sucking you towards it.

Gravity does not come from matter but is impinged on matter by photons of lengthy wavelength and where these wavelengths penetrate matter and get absorbed by matter over a wide area, secondary objects in the shadow of this photon stream will be pushed towards the primary object.

Think of two objects having force applied equally from all directions. Then bring those two objects closer together - what happens? Simple the outside pressure is reduced in the direction of the other object and they are "forced" together. Magic? no that is gravity at work.

Now take a black hole which absorbs all wavelengths and emits none. You have the theoretical maximum of gravity here. What happens when matter enters this event horizon? - assuming that it can get in. The event horizon would have to increase in size and the black hole would absorb a little more radiation and thus appear to gain mass.

Is there a balancing force that would resist this? don't know but at least in the real stable universe in which we exist it is nice to know that I don't know of anything - yet - that will stop a theoretical black hole from becoming a real black hole.

It is funny but gravity is more closely akin to objects at ground level on Earth being pressed upon on all sides by the atmosphere. If you can block the atmospheric pressure on one side you will be pushed that way not pulled that way.
jeffsaunders
not rated yet Jun 05, 2009
Thank you mysticshakra for those two links provided above. I did forget about the electric and magnetic forces at work compared with the force of "gravity" which I contend is just another manifestation of photon pressure of the universes background radiation.

Which I guess means that gravity or rather the shadow of background radiation that permeates the universe at 2.7 degrees Kelvin. would have to be pretty insignificant compared to the incandescence of electricity and magnetic forces at work.

Recently NASA published an article about the magnetic whirlwinds rising 1,000's of kilometers above the Earths surface and whirling at thousands of Kilometers per hour. Pretty impressive size and velocity yet satellites do travel straight through these vortexes with minimal problems.

Do the strong and weak nuclear forces and electrical/magnetic forces have enough strength to overcome the measurable strength of the photons - themselves electromagnetic in nature - generated by the entire universe?

Too much of what is currently built out of the standard Big Bang and the number of stretched and manipulated figures and fudge factors added have clouded the waters so much that I and many others are not fully sure what is mud and what is fish.