Most distant quasar found

This quasar provides an opportunity to explore a 100-million-year window in the history of the cosmos that was previously out of reach.

By ESO, Garching, Germany — Published: June 29, 2011

This artist’s impression shows how ULAS J1120+0641, a very distant quasar powered by a black hole with a mass two billion times that of the Sun, may have looked. ESO/M. Kornmesser

A team of European astronomers has used the European Southern Observatory’s (ESO) Very Large Telescope (VLT) and a host of other telescopes to discover and study the most distant quasar found to date. This brilliant beacon, powered by a black hole with a mass two billion times that of the Sun, is by far the brightest object yet discovered in the early universe.

“This quasar is a vital probe of the early universe,” said Stephen Warren from Imperial College London. “It is a very rare object that will help us to understand how supermassive black holes grew a few hundred million years after the Big Bang.”

Quasars are bright, distant galaxies that are believed to be powered by supermassive black holes at their centers. Their brilliance makes them powerful beacons that may help to probe the era when the first stars and galaxies were forming. The newly discovered quasar is so far away that its light probes the last part of the reionization era.

The quasar that has just been found, named ULAS J1120+0641, is seen as it was only 770 million years after the Big Bang. It took 12.9 billion years for its light to reach us.

Although more distant objects have been confirmed, such as a gamma-ray burst at redshift 8.2 and a galaxy at redshift 8.6, the newly discovered quasar is hundreds of times brighter than these.
Amongst objects bright enough to be studied in detail, this is the most distant by a large margin.

The next most distant quasar is seen as it was 870 million years after the Big Bang (redshift 6.4). Similar objects farther away cannot be found in visible-light surveys because their light, stretched by the expansion of the universe, falls mostly in the infrared part of the spectrum by the time it gets to Earth. The European UKIRT Infrared Deep Sky Survey (UKIDSS), which uses the United Kingdom’s dedicated infrared telescope in Hawaii, was designed to solve this problem. The team of astronomers hunted through millions of objects in the UKIDSS database to find those that could be the long-sought distant quasars, and eventually struck gold.

“It took us 5 years to find this object,” said Bram Venemans from ESO, Garching, Germany. “We were looking for a quasar with redshift higher than 6.5. Finding one that is this far away, at a redshift higher than 7, was an exciting surprise. By peering deep into the reionization era, this quasar provides a unique opportunity to explore a 100-million-year window in the history of the cosmos that was previously out of reach.”

The distance to the quasar was determined from observations made with the FORS2 instrument on ESO’s VLT and instruments on the Gemini North Telescope. Because the object is comparatively bright, it is possible to take a spectrum of it, which involves splitting the light from the object into its component colors. This technique allowed the astronomers to find out quite a lot about the quasar.

These observations showed that the mass of the black hole at the center of ULAS J1120+0641 is about two billion times that of the Sun. This high mass is hard to explain so early on after the Big Bang. Current theories for the growth of supermassive black holes predict a slow build-up in mass as the compact object pulls in matter from its surroundings.

“We think there are only about 100 bright quasars with redshift higher than 7 over the whole sky,” said Daniel Mortlock from Imperial College London. “Finding this object required a painstaking search, but it was worth the effort to be able to unravel some of the mysteries of the early universe.”

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JOHN MOES from MICHIGAN said:

"The quasar that has just been found, named ULAS J1120+0641, is seen as it was only 770 million years after the Big Bang. It took 12.9 billion years for its light to reach us."

At 770 million years after the BB and a red shift over 8 the quasar must have been less than 770 million light years away from this part of the universe when it emitted the light we are seeing, and a lot of matter lay between. There must have been plenty of matter close by to make such a big black hole. The 770 million light years of space then stretched to 12.9 now. The matter between just stayed in clumps that didn't expand. Does the space inside the clumps expand, or is it only the space outside the clumps that expands?

Submitted: 7/9/2011 7:51:27 PM (CST)

DONALD LIVERMAN from FLORIDA said:

The distances are awesome, and mind boggling. What interesting material. So very enjoyable and lucky to be here to further expand our knowledge of space and time.

Submitted: 7/6/2011 4:21:28 PM (CST)

STEPHEN ARMSTRONG from CALIFORNIA said:

Please stay on topic of the article. There are plenty of blogs for debate and conjecture and open discussion of any topic. Let's not go Newsvine with the Astronomy website.

Submitted: 7/5/2011 9:34:54 PM (CST)

ZACK MANOS from GEORGIA said:

The idea of the sun temp low enough to delay life forming on Earth is apparently consistent with real geological findings - Hadean life on Earth is perfectly named to describe it plus perhaps 80% of our 4.56BY with some prokaryotic development at best (the "extreme" of all extremophiles)! My intrigue starts with water formation before organic matter could organize into pyrimidine/purine-strands to kick start life with DNA! How much time is needed for such evolvement? I can't see 4.56BY even near the time necessary for evolutionary explosion we see - we are essentially seeing all complex life in the last half billion years pre-Cambrian to now... Put another way, the Sun ignites; our accretion disk of nebulous gas is dragged by the Sun as it traces out a mere 20 revolutions around the MWG. 99% of multicellular life forms evolve in our last one & current revolution #20? Here is where I have issues with math not adding up!

Submitted: 7/4/2011 11:36:55 AM (CST)

BILL SIMPSON from LOUISIANA said:

I can't get my mind around it, except to realize that it has probably wound down a lot by now. I guess. But it is probably a lot bigger by now too . A graph showing the typical rate of growth of a black hole from when it first formed would probably be interesting. Are all the growth curves similar? It may be an impossible problem to answer. Will these holes get torn up in the Big Rip. You need math to figure that out. I guess that they will. Scientific notation would definitely be needed in that calculation. I like the nice round 100 number of these things. It makes me wonder what happens when 2 galaxies collide. How long does it typically take for the black holes at the center to merge. I can imagine that is a pretty energetic process. I just read a theory that the Sun was too cool for life to form for the first few billion years of Earth's existence. That makes cutting the grass in the hot Sun seem not as bad, since we are lucky to have grass at all, and to be here to cut it.

Submitted: 6/30/2011 1:50:27 AM (CST)