Most distant quasar raises questions

Extreme age challenges theories of black hole formation

Astronomers peering at the early universe have glimpsed the most distant quasar yet. Powered by a black hole of 2 billion solar masses, the quasar appears as it did 12.9 billion years ago, when the universe as humans know it was just beginning to emerge from the Big Bang.

LOOKING BACK IN TIME A recently identified quasar emits 60 trillion times as much light as the sun. As shown in the illustration above, the quasar’s energy cleaves surrounding hydrogen atoms and produces the reddish bubble enveloping the massive, bright object. In the background are newborn galaxies. Gemini Observatory

The supermassive black hole is pulling enormous clumps of matter into its gravitational clutches. As a result, the quasar emits 60 trillion times as much light as the sun, an international team reports in the June 30 Nature.

The team identified the object from the U.K. Infrared Telescope’s Infrared Deep Sky Survey, which probes 5 percent of the sky in infrared wavelengths. Daniel Mortlock of Imperial College London, an author of the study, likens the process to panning for gold. “You see many shiny things in the infrared, but not all of them are nuggets,” he says. “We got a big nugget this time.”

Already, the uncharismatically named ULAS J1120+0641 is presenting both clues and puzzles about the early universe.

“The surprising thing is that this object is right at the farthest possible distance we could see,” Mortlock says. The object is so distant that because of the time it took the quasar’s light to reach Earth, astronomers are seeing it as it was just 770 million years after the Big Bang. While theorists had predicted quasars could form that soon after the Big Bang, none had anticipated seeing one so large in the embryonic universe.

“It is like finding a 6-foot-tall child in kindergarten,” says astrophysicist Marta Volonteri, at the University of Michigan in Ann Arbor.

Prevailing theories suggest that black holes form either from the tiny, dense objects left behind after the deaths of early stars, or they form from the direct collapse of cosmic gases. For the first theory to be correct, Volonteri says, ULAS J1120+0641 would have needed to begin growing before the beginning of time, suggesting that the direct collapse theory is better supported by the quasar’s discovery.

Scientists think there are maybe 100 distant, bright objects like the newly discovered quasar sprinkled throughout the entire sky, and astrophysicist Avi Loeb, at Harvard University, says he hopes sky surveys will find more of them. These quasars, if they exist, could act as beacons of light that help astronomers study the early universe.

The next steps include finding more of these giants in the early cosmic playground and studying the quasar’s neighborhood using different wavelengths.

The discovery is intriguing, notes Chris Willott, of National Research Council Canada, but he adds some caution: “This could be one charmed place in the universe where things are going on very quickly,” he says. “It’s always dangerous if you base everything you know on one object.”

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