Eduardo Banados had three nights to spot something that might not even exist: a supermassive black hole close to the beginning of time.
At the Las Campanas Observatory in Chile, perched high atop a mountain in the world's driest desert, he scanned for the signature of a massive, invisible sinkhole in the sky slurping up a whirlpool of brilliant, hot matter.
Just before sunrise on the third night, he found it. Way out at the very edge of the observable universe, there loomed a black hole 800 million times more massive than the sun. The signal had traveled more than 13 billion light-years across time and space to reach Banados' telescope.
The object's size is stunning, Banados said, because it existed just 690 million years after the Big Bang, when the universe was just 5 percent of its current age and still emerging from an enigmatic era known as "the Dark Ages."
"If the universe was a 50-year-old person," Banados explained. "Now we have a photograph of that person as a toddler . . . when they were two and a half."
This state of affairs lasted for hundreds of millions of years. Yet sometime during this inscrutable period, the universe as we know it emerged. Gravity pulled hydrogen into the first gas clouds, from which the first stars were born. The radiation from the newly formed objects broke hydrogen atoms apart into their constituent particles - protons and electrons - finally dispelling the chilly fog.
The absence of light sources during the Dark Ages makes it difficult to probe this period with telescopes. The hydrogen fog further complicates matters. Banados says it is as though someone went through the universe's childhood photo album and ripped out all the pictures of its most formative years.
That hope is what drove Banados, an astronomer at the Carnegie Observatories in California, to the Chilean mountaintop in March. It was not entirely clear whether he'd be able to find a quasar so far away. Supermassive black holes swallow up huge amounts of matter, squeezing the equivalent mass of several hundred thousand suns into a space so small that gravity wraps around it like an invisibility cloak and causes it to vanish. An object like that needs a long time to grow and more matter than might have been available in the young universe.
"This is what we are trying to push forward." Banados said. "At some point these shouldn't exist. When is that point? We still don't know."
In a companion paper published in the Astrophysical Journal Letters, the scientists report another odd finding: The galaxy where ULAS J1342+0928 dwells was generating new stars "like crazy," Banados said. Objects the size of our sun were emerging 100 times as frequently as they do in our own galaxy today.
"To build stars you need dust," Banados said. "But it's really hard to form all this dust in such little time on cosmic scales - that requires some generations of supernovae to explode."
During the universe's toddler years, there hadn't been time for several rounds of stars living and dying. So where were the ingredients for all these new stars coming from?
Observations of the light coming from the quasar point to a third curiosity: This object lived when roughly half the universe's hydrogen was still neutral. That places it right smack dab in the middle of the reionization epoch, when the light of the first celestial objects burned away the Dark Ages fog.
"Maybe we are probing the region now where the first stars and galaxies formed," Banados said. The quasar "is basically a gold mine for follow-up studies of this 2 1/2-year-old universe."
(This story has not been edited by NDTV staff and is auto-generated from a syndicated feed.)
At the Las Campanas Observatory in Chile, perched high atop a mountain in the world's driest desert, he scanned for the signature of a massive, invisible sinkhole in the sky slurping up a whirlpool of brilliant, hot matter.
Just before sunrise on the third night, he found it. Way out at the very edge of the observable universe, there loomed a black hole 800 million times more massive than the sun. The signal had traveled more than 13 billion light-years across time and space to reach Banados' telescope.
The object's size is stunning, Banados said, because it existed just 690 million years after the Big Bang, when the universe was just 5 percent of its current age and still emerging from an enigmatic era known as "the Dark Ages."
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"If the universe was a 50-year-old person," Banados explained. "Now we have a photograph of that person as a toddler . . . when they were two and a half."
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This state of affairs lasted for hundreds of millions of years. Yet sometime during this inscrutable period, the universe as we know it emerged. Gravity pulled hydrogen into the first gas clouds, from which the first stars were born. The radiation from the newly formed objects broke hydrogen atoms apart into their constituent particles - protons and electrons - finally dispelling the chilly fog.
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The absence of light sources during the Dark Ages makes it difficult to probe this period with telescopes. The hydrogen fog further complicates matters. Banados says it is as though someone went through the universe's childhood photo album and ripped out all the pictures of its most formative years.
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That hope is what drove Banados, an astronomer at the Carnegie Observatories in California, to the Chilean mountaintop in March. It was not entirely clear whether he'd be able to find a quasar so far away. Supermassive black holes swallow up huge amounts of matter, squeezing the equivalent mass of several hundred thousand suns into a space so small that gravity wraps around it like an invisibility cloak and causes it to vanish. An object like that needs a long time to grow and more matter than might have been available in the young universe.
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"This is what we are trying to push forward." Banados said. "At some point these shouldn't exist. When is that point? We still don't know."
In a companion paper published in the Astrophysical Journal Letters, the scientists report another odd finding: The galaxy where ULAS J1342+0928 dwells was generating new stars "like crazy," Banados said. Objects the size of our sun were emerging 100 times as frequently as they do in our own galaxy today.
"To build stars you need dust," Banados said. "But it's really hard to form all this dust in such little time on cosmic scales - that requires some generations of supernovae to explode."
During the universe's toddler years, there hadn't been time for several rounds of stars living and dying. So where were the ingredients for all these new stars coming from?
Observations of the light coming from the quasar point to a third curiosity: This object lived when roughly half the universe's hydrogen was still neutral. That places it right smack dab in the middle of the reionization epoch, when the light of the first celestial objects burned away the Dark Ages fog.
"Maybe we are probing the region now where the first stars and galaxies formed," Banados said. The quasar "is basically a gold mine for follow-up studies of this 2 1/2-year-old universe."
(This story has not been edited by NDTV staff and is auto-generated from a syndicated feed.)
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