STScI-01EVT6ESD5K1F1CK14MPRZACAZ hubble.jpg
The star cluster Omega Centauri contains millions of stars. The movement of some stars suggests that an intermediate-sized black hole lies at its center.

Astronomers have used the Hubble Space Telescope to find evidence of an elusive kind of black hole, one that’s about 8,000 times more massive than our sun.

What makes this black hole special is its size, according to a report on the discovery in the journal Nature.

It’s far more massive than a garden-variety black hole, the type that’s created when a dead star collapses in on itself. But it’s also not nearly as big as the kind of supermassive black hole that lurks in the center of galaxies and can hold on the order of hundreds of thousands to millions of suns.

Scientists have long been on the hunt for medium-sized black holes like this new one, because finding them could shed light on the myriad ways that black holes can form and why some grow into gargantuan monsters.

Despite plenty of effort over the years, however, scientists haven’t had luck in finding solid examples of black holes in the so-called intermediate size range, which would include any black hole that’s between 100 to 100,000 times the mass of the sun.

“So people have wondered, is it difficult to find them because they are just not there, or because it's difficult to detect them?” says Maximilian Häberle of the Max Planck Institute for Astronomy, Heidelberg, Germany.

He and some colleagues recently decided to look for one in a large, bright star cluster known as Omega Centauri. This densely-packed, spherical cloud of millions of stars is about 17,000 light years away.

Black holes can’t be observed directly, since their gravity pulls in everything, including light. But researchers can look to see if the gravity of a black hole is affecting nearby objects, including stars.

And the researchers knew that the stars in this particular cluster were being continuously observed by the Hubble Space Telescope, which takes images of the cluster’s central region every year.

“This is actually for technical reasons, to calibrate the instruments,” says Häberle.

Because the telescope had taken high-quality observations that went back more than two decades, Häberle and his colleagues were able to precisely measure the motion of 1.4 million stars in the cluster.

“Our list of stars for which we have measured motions is much, much larger than any previous efforts,” he says, adding that the stars are “all moving in random directions and like a swarm of insects.”

Ultimately, the researchers were able to pick out seven stars in the center that are moving much faster than the others. These stars are actually moving so fast that they really should just shoot out of the star cluster and be gone forever.

The fact that they remain stuck and concentrated at the center, says Häberle, “means that there must be something that is pulling on them gravitationally such that they don't escape. And the only object that can be so massive is an intermediate-mass black hole with a minimum mass of at least 8,000 solar masses.”

The black hole is unlikely to be any bigger than about 50,000 times as massive as the sun, he says, because if that were the case then scientists would expect many more stars to be affected by its gravity.

He notes that there was a previous claim of finding an intermediate-sized black hole candidate in this cluster that dates back to 2008, but that was disputed.

This time around, he says, “I think our evidence is very robust” because of the additional years of data.

What’s more, future observations with the James Webb Space Telescope are already planned, and this powerful telescope will be able to look for tell-tale signs of gas that’s being heated up as it falls into the black hole.

“This is really exciting, right? This is only the second black hole where you can see individual stars whizzing around the black hole,” says Jenny Greene, an astrophysicist with Princeton University.

She notes that the only similar observation was Nobel prize-winning work that saw stars flying around the black hole at the center of our Milky Way galaxy, a supermassive one that’s about four million times as massive as our sun.

“So I think it’s really a big deal. And it’s a much lower-mass black hole,” she says.

No one knows how a black hole of this size gets created.

One possibility is that small black holes might merge together into a larger one. Evidence for that comes from the detection of gravitational waves from two black holes colliding, an event that spawned a black hole about 150 times more massive than the sun.

Another possible way to grow medium-sized black holes, recently suggested by astronomers, is that many stars might collide in a dense cluster like Omega Centauri and become a single very massive star. Later, that big star would collapse into an intermediate-sized black hole.

Understanding where mid-sized black holes lie and how they grow may help scientists understand what role they could play in the evolution of even bigger ones that sit at the heart of galaxies.

The newly discovered black hole “really will tell us important information about how those big black holes first formed and grew,” says Greene.

Such supermassive black holes seem to have appeared surprisingly soon after the universe got started, just a few hundred million years after the Big Bang.

That’s according to new observations made with the James Webb Space Telescope, which left astronomers puzzling over how a black hole could get so big so fast.

Before those observations, says Greene, she thought that galaxies grew first and then black holes formed at their centers. “Now, I’m less sure,” she says. “There is some tantalizing evidence now that black holes grew up earlier than their galaxies.”

Intermediate-sized black holes that exist today could be relics left over from that early black hole creation process, says Greene, and could provide clues about how it transpired.

“Ultimately to get a full picture, we need more than just one,” she says, “but this is really opening the door.”

Transcript

SCOTT DETROW, HOST:

If black holes were T-shirts, then scientists rummaging through the clothes rack that is our universe have managed to pull out only two sizes, small and XXL. They would love to find a black hole in a size medium, and they may have just nabbed one. NPR's Nell Greenfieldboyce explains why this is such a big deal.

NELL GREENFIELDBOYCE, BYLINE: Black holes are weird cosmic beasts that are so massive, their gravity sucks in everything, including light. Sometimes they form when a star dies and collapses in on itself. This produces a black hole that can be, say, 10 times as massive as our sun. Then there's a kind of black hole that's way bigger, supermassive black holes, which can be millions of times more massive than our sun. So there's these two extremes, and scientists have looked for black holes that would fall somewhere in the middle.

MAXIMILIAN HABERLE: But it has been very difficult to find them. And so people have wondered, is it difficult to find them because they are just not there?

GREENFIELDBOYCE: Maximilian Haberle is with the Max Planck Institute for Astronomy in Germany. He and some colleagues recently went searching for an intermediate-sized black hole. They looked in a relatively nearby star cluster. It's a large ball-shaped cloud made of millions of stars, like a swarm of insects. And it turns out the Hubble Space Telescope has looked at this cluster a lot.

HABERLE: So every year, they take some images of the central region. And this is actually for technical reasons, to calibrate the instrument.

GREENFIELDBOYCE: Having so many images, going back over 20 years, let the researchers precisely track the motion of 1.4 million stars. They found seven stars in the center of the cluster that were moving super fast, so fast that you'd expect them to shoot out of this ball of stars and be gone forever.

HABERLE: The fact that we can see them, they are concentrated in the center means that there must be something that is pulling on them gravitationally, such that they don't escape.

GREENFIELDBOYCE: He says the only thing that can be is an invisible black hole, about 8,000 times more massive than our sun - a black hole that is not small and not supermassive, but something in between. A report on the find in the journal Nature has other astronomers thrilled. Jenny Green studies black holes at Princeton University.

JENNY GREENE: This is really exciting, right? This is only the second black hole where you can see individual stars whizzing around the black hole.

GREENFIELDBOYCE: She says the only other place astronomers have seen this is at the center of our Milky Way around the supermassive black hole that lives there. Such supermassive black holes are mysterious. Scientists aren't sure when and how they grew so large. Greene says being able to study less massive ones, like this new one, could provide clues about how these enormous monsters came to be.

Nell Greenfieldboyce, NPR News.

(SOUNDBITE OF LOLA YOUNG SONG, "CONCEITED") Transcript provided by NPR, Copyright NPR.

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