3 Black Holes Caught Eating Massive Stars in NASA Data

A new study using NASA, ESA, and other institutions’ data has discovered three extreme examples of supermassive black holes feasting on massive stars, releasing more energy than 100 supernovae.
The events, known as “extreme nuclear transients,” are rare occurrences that can help unveil massive supermassive black holes that are usually quiet, and could provide insights into the growth of these black holes throughout the universe.
These events unleash enormous amounts of high-energy radiation on the central regions of their host galaxies, producing high-energy light that takes over 100 days to reach peak brightness and more than 150 days to dim to half of its peak.
The study used data from NASA’s Neil Gehrels Swift Observatory, WISE spacecraft, and ground-based observatories to confirm that these events are related to black holes, not stellar explosions or other phenomena, and characterized dust in the environments of each black hole.
A future telescope, the Nancy Grace Roman Space Telescope, is designed to detect these rare explosions from more than 12 billion years ago, offering a new way to explore how stars, galaxies, and black holes formed and evolved over time.

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3 Black Holes Caught Eating Massive Stars in NASA Data

A disk of hot gas swirls around a black hole in this illustration. The stream of gas is what remains of a star that was pulled apart by the black hole. A cloud of hot plasma above the black hole is known as a corona.

A disk of hot gas swirls around a black hole in this illustration. Some of the gas came from a star that was pulled apart by the black hole, forming the long stream of hot gas on the right, feeding into the disk.

Credits:
NASA/JPL-Caltech

Black holes are invisible to us unless they interact with something else. Some continuously eat gas and dust, and appear to glow brightly over time as matter falls in. But other black holes secretly lie in wait for years until a star comes close enough to snack on.

A new study using space and ground-based data from NASA, ESA (European Space Agency), and other institutions describes three extreme examples of supermassive black holes feasting on massive stars. These events released more energy than 100 supernovae, and represent the most energetic type of cosmic explosion since the big bang discovered so far.

Each supermassive black hole sits at the center of a distant galaxy, and suddenly brightened when it destroyed a star three to 10 times heavier than our Sun. The brightness then lasted for several months.

Scientists describe these rare occurrences as a new category of cosmic events called “extreme nuclear transients.” Looking for more of these extreme nuclear transients could help unveil some of the most massive supermassive black holes in the universe that are usually quiet.

“These events are the only way we can have a spotlight that we can shine on otherwise inactive massive black holes,” said Jason Hinkle, graduate student at the University of Hawaii and lead author of a new study in the journal Science Advances describing this phenomenon.

This illustration shows a glowing stream of material from a star as it is being devoured by a supermassive black hole in a tidal disruption flare. Astronomers gained new insights into tidal disruption flares thanks to data from NASA's WISE.

This illustration shows a glowing stream of material from a star as it is being devoured by a supermassive black hole. When a star passes within a certain distance of a black hole — close enough to be gravitationally disrupted — the stellar material gets stretched and compressed as it falls into the black hole.

NASA/JPL-Caltech

These events unleash enormous amounts of high-energy radiation on the central regions of their host galaxies. “That has implications for the environments in which these events are occurring,” Hinkle said. “If galaxies have these events, they’re important for the galaxies themselves.”

The stars’ destruction produces high-energy light that takes over 100 days to reach peak brightness, then more than 150 days to dim to half of its peak. The way the high-energy radiation affects the environment results in lower-energy emissions that telescopes can also detect.

One of these star-destroying events, nicknamed “Barbie” because of its catalog identifier ZTF20abrbeie, was discovered in 2020 by the Zwicky Transient Facility at Caltech’s Palomar Observatory in California, and documented in two 2023 studies. The other two black holes were detected by ESA’s Gaia mission in 2016 and 2018 and are studied in detail in the new paper.

NASA’s Neil Gehrels Swift Observatory was critical in confirming that these events must have been related to black holes, not stellar explosions or other phenomena. The way that the X-ray, ultraviolet, and optical light brightened and dimmed over time was like a fingerprint matching that of a black hole ripping a star apart.

Scientists also used data from NASA’s WISE spacecraft, which was operated from 2009 to 2011 and then was reactivated as NEOWISE and retired in 2024. Under the WISE mission the spacecraft mapped the sky at infrared wavelengths, finding many new distant objects and cosmic phenomena. In the new study, the spacecraft’s data helped researchers characterize dust in the environments of each black hole. Numerous ground-based observatories additionally contributed to this discovery, including the W. M. Keck Observatory telescopes through their NASA-funded archive and the NASA-supported Near-Earth Object surveys ATLAS, Pan-STARRS, and Catalina.

“What I think is so exciting about this work is that we’re pushing the upper bounds of what we understand to be the most energetic environments of the universe,” said Anna Payne, a staff scientist at the Space Telescope Science Institute and study co-author, who helped look for the chemical fingerprints of these events with the University of Hawaii 2.2-meter Telescope.

A Future Investigators in NASA Earth and Space Science and Technology (FINESST) grant from the agency helped enable Hinkle to search for these black hole events. “The FINESST grant gave Jason the freedom to track down and figure out what these events actually were,” said Ben Shappee, associate professor at the Institute for Astronomy at the University of Hawaii, a study coauthor and advisor to Hinkle.

Hinkle is set to follow up on these results as a postdoctoral fellow at the University of Illinois Urbana-Champaign through the NASA Hubble Fellowship Program. “One of the biggest questions in astronomy is how black holes grow throughout the universe,” Hinkle said.

The results complement recent observations from NASA’s James Webb Space Telescope showing how supermassive black holes feed and grow in the early universe. But since only 10% of early black holes are actively eating gas and dust, extreme nuclear transients — that is, catching a supermassive black hole in the act of eating a massive star — are a different way to find black holes in the early universe.

Events like these are so bright that they may be visible even in the distant, early universe. Swift showed that extreme nuclear transients emit most of their light in the ultraviolet. But as the universe expands, that light is stretched to longer wavelengths and shifts into the infrared — exactly the kind of light NASA’s upcoming Nancy Grace Roman Space Telescope was designed to detect.

With its powerful infrared sensitivity and wide field of view, Roman will be able to spot these rare explosions from more than 12 billion years ago, when the universe was just a tenth of its current age. Scheduled to launch by 2027, and potentially as early as fall 2026, Roman could uncover many more of these dramatic events and offer a new way to explore how stars, galaxies, and black holes formed and evolved over time.

“We can take these three objects as a blueprint to know what to look for in the future,” Payne said.

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Q. What is the new category of cosmic events called “extreme nuclear transients” that scientists have discovered?

A. These events represent the most energetic type of cosmic explosion since the big bang, and are characterized by a sudden brightening of supermassive black holes when they destroy massive stars.

Q. How do these extreme nuclear transients affect the environment around the host galaxies?

A. The high-energy radiation produced during these events can unleash enormous amounts of energy on the central regions of their host galaxies, resulting in lower-energy emissions that telescopes can also detect.

Q. What is unique about the way these events emit light?

A. These events emit most of their light in the ultraviolet, but as the universe expands, this light is stretched to longer wavelengths and shifts into the infrared.

Q. How will NASA’s Nancy Grace Roman Space Telescope be able to spot these rare explosions from more than 12 billion years ago?

A. The telescope’s powerful infrared sensitivity and wide field of view will allow it to detect these events even in the distant, early universe.

Q. What is the significance of finding these extreme nuclear transients?

A. These events can help unveil some of the most massive supermassive black holes in the universe that are usually quiet, providing a new way to explore how stars, galaxies, and black holes formed and evolved over time.

Q. Who is the lead author of the study describing this phenomenon?

A. Jason Hinkle, a graduate student at the University of Hawaii, is the lead author of the study in the journal Science Advances.

Q. What type of grant helped enable Hinkle to search for these black hole events?

A. A Future Investigators in NASA Earth and Space Science and Technology (FINESST) grant from the agency gave Hinkle the freedom to track down and figure out what these events actually were.

Q. How long does it take for the high-energy radiation produced during these events to reach peak brightness?

A. The high-energy light takes over 100 days to reach peak brightness, then more than 150 days to dim to half of its peak.

Q. What is the potential impact of discovering these extreme nuclear transients on our understanding of black holes and the universe?

A. These discoveries can provide a new way to explore how stars, galaxies, and black holes formed and evolved over time, shedding light on some of the most fundamental questions in astronomy.