A Gamma-Ray Burst Just Revealed a ‘Goldilocks’ Black Hole in The Early Universe
Scientists have reported the discovery of a rare, medium-sized black hole that may help answer one of the more tantalizing questions in astronomy: how do their supermassive counterparts come into being?
There are two well-known sizes of black hole – at one end, so-called stellar-class ones which are typically three to ten times the mass of our Sun – and at the other, supermassive ones, found at the center of most galaxies, including the Milky Way, which are millions to billions times heavier.
The newly detected ‘goldilocks’ black hole – about 55,000 solar masses – could be a missing link between these two extremes, scientists suggested Monday in the journal Nature Astronomy.
Up to now, only a handful of intermediate-mass black holes – between 100 and 100,000 solar masses – have been detected, and none have been squarely in the middle of that range.
A black hole is a celestial object that compresses a huge mass into an extremely small space. Their gravitational pull is so strong nothing can escape them, not even light.
Stellar-class black holes form when a dying star collapses, but astronomers have yet to figure out the origin story of the larger, matter-eating monsters.
“How do we get so many supermassive black holes in the Universe?” asked co-author Rachel Webster, a professor at the University of Melbourne.
Senior author Eric Thrane, a professor at Monash University, said the newly discovered black hole “could be an ancient relic, a primordial black hole created before the first stars and galaxies formed.”
“These early black holes may be the seeds of the supermassive black holes that live in the hearts of galaxies today.”
Born that way?
The new specimen was observed indirectly thanks to a slight deviation in light from a stellar explosion in the early Universe, some 8 billion light-years distant.
Using a technique pioneered by Webster, astronomers analyzed thousands of these gamma-ray bursts – caused either by the violent collapse of a star or the merger of two stars – looking for signs of gravitational lensing.
This occurs when an object – in this case, the intermediate black hole – acts as a lens and fleetingly bends the path of the light as it travels toward Earth, such that astronomers see the same flash twice.
While Thrane, Webster and lead author James Paynter, a PhD candidate, were able to measure the mass of their intermediate black hole with precision, they could only speculate on how it was formed.
“Broadly, there are three possibilities,” Webster told AFP.
It could have been forged from the merger between two lesser black holes, as was true for another, much smaller intermediate black hole discovered in May 2019.