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Cosmic Reservoir Surrounding a Monster Black Hole --140 Trillion Times Earth's Oceans (Today's Most Popular)




In 2011, two teams of astronomers discovered the largest and farthest reservoir of water ever detected in the universe. The water, equivalent to 140 trillion times all the water in the world's ocean, surrounds a huge, feeding black hole, called a quasar, more than 12 billion light-years away. "This thing is at the edge of the dark ages," before the first stars in the universe were born, said Chris Carilli, an astronomer at the NSF's National Radio Astronomy Observatory (NRAO).

The quasar, APM 08279+5255, was discovered in 1998. Observations with optical and infrared telescopes revealed that the quasar, a young galaxy with a voracious black hole at its center (image above), was forming new stars rapidly in a starburst. At a distance of more than 12 billion light-years, the quasar is seen as it was more than 12 billion years ago, just a billion or so years after the Big Bang.
"The environment around this quasar is very unique in that it's producing this huge mass of water," said Matt Bradford, a scientist at NASA's Jet Propulsion Laboratory in Pasadena, Calif. "It's another demonstration that water is pervasive throughout the universe, even at the very earliest times." Bradford leads one of the teams that made the discovery. 

A quasar is powered by an enormous black hole that steadily consumes a surrounding disk of gas and dust. As it eats, the quasar spews out huge amounts of energy. Both groups of astronomers studied the particular quasar, APM 08279+5255, which harbors a black hole 20 billion times more massive than the sun and produces as much energy as a thousand trillion suns. 

Astronomers expected water vapor to be present even in the early, distant universe, but had not detected it this far away before. There's water vapor in the Milky Way, although the total amount is 4,000 times less than in the quasar, because most of the Milky Way's water is frozen in ice. 

Water vapor is an important trace gas that reveals the nature of the quasar. In this particular quasar, the water vapor is distributed around the black hole in a gaseous region spanning hundreds of light-years in size (a light-year is about six trillion miles). Its presence indicates that the quasar is bathing the gas in X-rays and infrared radiation, and that the gas is unusually warm and dense by astronomical standards. Although the gas is at a chilly minus 63 degrees Fahrenheit (minus 53 degrees Celsius) and is 300 trillion times less dense than Earth's atmosphere, it's still five times hotter and 10 to 100 times denser than what's typical in galaxies like the Milky Way.

Measurements of the water vapor and of other molecules, such as carbon monoxide, suggest there is enough gas to feed the black hole until it grows to about six times its size. Whether this will happen is not clear, the astronomers say, since some of the gas may end up condensing into stars or might be ejected from the quasar. 

Bradford's team made their observations starting in 2008, using an instrument called "Z-Spec" at the California Institute of Technology's Submillimeter Observatory, a 33-foot (10-meter) telescope near the summit of Mauna Kea in Hawaii. Follow-up observations were made with the Combined Array for Research in Millimeter-Wave Astronomy (CARMA), an array of radio dishes in the Inyo Mountains of Southern California. 

The second group, led by Dariusz Lis, senior research associate in physics at Caltech and deputy director of the Caltech Submillimeter Observatory, used the Plateau de Bure Interferometer in the French Alps to find water. In 2010, Lis's team serendipitously detected water in APM 8279+5255, observing one spectral signature. Bradford's team was able to get more information about the water, including its enormous mass, because they detected several spectral signatures of the water. 

The Daily Galaxy via

The image at the top of the page is NRAO artist Geraint Lewis' conception of the APM 08279+5255 system, with the bright quasar at right, the large, massive gas cloud on the left.



I understand science says that huge quasars were the rule of the day at the universe beginnings 15 bya, or should be. The redshift controversy places them 1.9 t0 3 bya in one fell swoop. That aside, there is the issue of their giant size which would require magnetic fields to contain the gas under pressure. This intake of pure gas would explain the star making, the dirty gas explained by the stars birth themselves. And the water? Would this production be another result of the narrow requirement for pure gas? Would any time astronomy finds 'water' mean that a LT (light terminus) starbody would be in a particularly rich field of pure gas and able to make the heated gas and oxygen for water?

"This thing is at the edge of the dark ages," before the first stars in the universe were born"

As I understand it, higher mass nuclei (> Helium) are only formed in large quantities in solar cores. Where did this massive reservoir get all the Oxygen? What mechanism in the early universe constructed the higher Z nuclei?

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