Researchers have discovered the oldest black hole ever observed, dating from the dawn of the universe, and found that it’s still in the process of consuming its host galaxy.
The international team, led by the University of Cambridge, used the James Webb Space Telescope to detect the black hole, which dates from 400 million years after the Big Bang, more than 13 billion years ago.
The results, which lead author Roberto Maiolino says are “a giant leap forward,” are reported in the journal Nature.
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Baby Universe, Big Appetite: Supermassive Black Hole Forces Growth Theory Rewrite
That this surprisingly massive black hole—a few million times the mass of our sun—even exists so early in the universe challenges our assumptions about how they form and grow.
Astronomers believe that the supermassive black holes found at the center of galaxies like the Milky Way grew to their current size over billions of years. But the size of this new discovery suggests that they might form in other ways: they might be ‘born big’ or they can consume matter at a rate that’s five times higher than had been thought possible.
According to standard models, supermassive black holes form from the remnants of dead stars, which collapse and may form a mass about a hundred times the mass of the Sun. If it grew in the expected way, this newly detected black hole would take about a billion years to grow to its observed size. The catch is that the universe was not yet a billion years old when this black hole was detected.
“It’s very early in the universe to see a black hole this massive, so we’ve got to consider other ways they might form,” said Maiolino, from Cambridge’s Cavendish Laboratory and Kavli Institute of Cosmology.
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He suggests that because the first galaxies to form were extremely gas-rich, “they would have been like a buffet for black holes.”
Indeed, this ancient black hole seems to have the metabolism of one who frequents buffets, because the scientists determined it’s gobbling up surrounding matter much more vigorously than its siblings at later epochs.
The young host galaxy, called GN-z11, glows from such an energetic black hole at its center. Black holes cannot be directly observed, but instead, they are detected by the telltale glow of a swirling ‘accretion disc,’ which forms near the edges of a black hole. The gas in the accretion disc becomes extremely hot and starts to glow and radiate energy in the ultraviolet range. This strong glow is how astronomers are able to detect black holes.
JWST Reveals Cosmic Showdown: Black Hole Feast Puts Galaxy’s Future on the Menu
GN-z11 is a compact galaxy, about one hundred times smaller than the Milky Way, but the black hole is likely harming its development. When black holes consume too much gas, it pushes the gas away like an ultra-fast wind. This ‘wind’ could stop the process of star formation, slowly killing the galaxy, but it will also kill the black hole itself, as it would also cut off the black hole’s source of ‘food’.
Maiolino says that the gigantic leap forward provided by JWST makes this the most exciting time in his career.
“It’s a new era: the giant leap in sensitivity, especially in the infrared, is like upgrading from Galileo’s telescope to a modern telescope overnight,” he said. “Before Webb came online, I thought maybe the universe wasn’t so interesting when you went beyond what we could see with the Hubble Space Telescope. But that hasn’t been the case at all; the universe has been quite generous in what it’s showing us, and this is just the beginning.”
Maiolino says that the sensitivity of JWST means that even older black holes may be found in the coming months and years. Maiolino and his team are hoping to use future observations from JWST to try to find smaller seeds of black holes, which may help them untangle the different ways that black holes might form, whether they start out large or grow fast.
