First data from XRISM space mission provides new perspective on supermassive black holes

September 20, 2024
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A small black circle sits at the center of an illustration, representing a black hole. A thin blue spiral shows energetic material swirling around the black hole. The edge of the spiral gives way to a larger, thicker and more diffuse and broader red and orange cloud. Shooting up from the black hole, perpendicular to the cloud, is a narrow jet of radiation shown in bluish white.
An artist’s rendering of what’s called an active galactic nucleus at the center of NGC 4151. The galaxy’s black hole sits at the center, immediately surrounded by an accretion disk shown in blue. Image credit: JAXA

Some of the first data from an international space mission is confirming decades worth of speculation about the galactic neighborhoods of supermassive black holes.

More exciting than the data, though, is the fact that the long-awaited satellite behind it—the X-Ray Imaging and Spectroscopy Mission or XRISM—is just getting started providing such unparalleled insights.

“We have found the right tool for developing an accurate picture of the unexplored orders of magnitude around supermassive black holes,” Jon Miller, professor of astronomy at the University of Michigan, said of XRISM.

Jon Miller
Jon Miller

“We’re beginning to see clues of what that environment really looks like.”

The Japanese Aerospace Exploration Agency, or JAXA, which teamed up with NASA and the European Space Agency to create and launch XRISM, announced the new results Sept. 20.

The results were published Sept. 19 in two peer-reviewed studies, with Miller being the lead author of one accepted to The Astrophysical Journal Letters. He and more than 100 co-authors from around the world investigated what’s called an active galactic nucleus, which includes a supermassive black hole and its extreme surroundings.

To do this, they relied on XRISM’s unparalleled ability to gather and measure spectra of X-rays emitted by cosmic phenomena.

Lia Corrales
Lia Corrales

“It is truly exciting that we are able to gather X-ray spectra with such unprecedented high resolution, particularly for the hottest plasmas in the universe,” said Lia Corrales, U-M assistant professor of astronomy and a co-author of both XRISM publications.

“Spectra are so rich with information, we will surely be working to fully interpret the first datasets for many years to come.”

Accretion disks with a twist

Space exploration enthusiasts may know that the Chandra X-ray Observatory—what NASA calls its flagship X-ray telescope—recently celebrated its 25th anniversary of operating in space.

What’s less well known is that, over the past 25 years, an international cohort of scientists, engineers and space agency officials have been attempting to launch similarly sophisticated, but different X-ray missions.

The goal of these attempts was to provide high-quality, complementary data to better understand what Chandra and other telescopes were seeing. XRISM is now delivering that data.

With their data set, Miller, Corrales and their colleagues have solidified a hypothesis about structures called accretion disks near supermassive black holes in active galactic nuclei.

These disks can be thought of like vinyl records made of gas and other loose particles from a galaxy being spun by the spectacular gravity of the black holes at their centers. By studying accretion disks, researchers can better understand what’s happening around the black hole and how it impacts the lifecycle of its host galaxy.

By probing the center of a galaxy called NGC 4151, more than 50 million light years away, the XRISM collaboration confirmed that the disk’s shape isn’t as simple as once thought.

“What we’re seeing is that the record isn’t flat. It has a twist or a warp,” Miller said. “It also appears to get thicker toward the outside.”

An artist's rendering shows a disk of matter swirling around a black hole—a small black orb at the center of the image. As you get closer to the black hole, the matter gets more energetic, shown as colors brighter shades of red-orange to purple to blue. Next to the black hole, the disk also starts to warp.
XRISM has shown that the accretion disk surrounding a black hole in an active galactic nucleus is warped, confirming earlier hypotheses reflected in this artist’s conception from 2015. Image credit: International Center for Radio Astronomy Research

Although suggestions of this more complex geometry have emerged in other data over the past two and a half decades, the XRISM results are the strongest direct evidence for it.

“We had hints,” Miller said. “But somebody in forensics would say that we couldn’t have convicted anyone with what we had.”

The team also found that the accretion disk appears to be losing a lot of its gas. Again, scientists have theories about what happens to this material, but Miller said XRISM will enable researchers to find more definitive answers.

“It has been very hard to say what the fate of that gas is,” he said. “Actually finding the direct evidence is the hard work that XRISM can do.”

And XRISM isn’t just allowing researchers to think about existing theories in new ways. It’s enabling them to investigate parts of space that were invisible to them before.

The missing link

For all the talk of their gravitational pull being so strong that not even light can escape it, black holes are still responsible for creating a whole lot of electromagnetic radiation that we can detect.

For instance, the Event Horizon Telescope—a network of instruments on Earth sensitive to radiation emitted as radio waves—has enabled astronomers to zoom in and see the very edge of two different black holes.

There are other instruments on Earth and in space that detect different bands of radiation, including X-rays and infrared light, to provide larger, galaxy-scale views of the environs of black holes.

But scientists have lacked high-resolution tools to determine what was going on between those two scales, from right next to the black hole up to the size of its host galaxy. And that space between is where accretion disks and other interesting celestial structures exist.

If you were to divide the scale of the zoomed-out view of a black hole by that of its close-up, you’d get a number close to 100,000. To a physicist, each zero is an order of magnitude, meaning the gap in coverage spanned five orders of magnitude.

“When it comes to understanding how gas gets into a black hole, how some of that gas is lost and how the black hole impacts its host galaxy, it’s those orders of magnitude that really matter,” Miller said.

XRISM now gives researchers access to those scales by looking for X-rays emitted by iron around black holes and relying on the “S” in its acronym: spectroscopy.

Rather than using X-ray light to construct an image, XRISM’s spectroscopy instrument detects the energy of individual X-rays, or photons. Researchers can then see how many photons were detected with a particular energy across a range, or spectrum, of energies.

By collecting, studying and comparing spectra from different parts of the regions near a black hole, researchers are able to learn more about the processes afoot.

“We joke that spectra put the ‘physics’ in ‘astrophysics,'” Miller said.

A cross section of an active galactic nucleus and its different components. A accretion disk extends out from a central black hole, getting thicker towards its outer edge. The accretion disk bulges into a broader red broad-line region, which is surrounded on its outside by a larger, donut-shaped torus. An inset shows that the X-ray spectra taken by XRISM look different for each region.
A schematic shows how the XRISM mission can take spectra from different parts of an active galactic nucleus: the thin, hot accretion disk; an intermediate zone called the broad-line region; and a cooler, more diffuse torus. Image credit: JAXA

Although there are other operational X-ray spectroscopy tools, XRISM’s is the most advanced and relies on a microcalorimeter, dubbed “Resolve.” This turns the incident X-ray energy into heat rather than, say, a more conventional electrical signal.

“Resolve is allowing us to characterize the multi-structured and multi-temperature environment of supermassive black holes in a way that was not possible before,” Corrales said.

XRISM provides researchers with 10 times better energy resolution compared with what they’ve had before, Miller said. Scientists have been waiting for an instrument like this for 25 years, but it hasn’t been for a lack of trying.

If at first you don’t succeed

Years before its 1999 launch, Chandra was initially conceived of as the Advanced X-Ray Astrophysics Facility, a single mission that would fly with state-of-the-art technology for both X-ray imaging and spectroscopy.

That, however, proved to be too expensive, so it was divided into the Chandra telescope and a spectroscopy mission called Astro-E, whose development was led by JAXA. Unfortunately, Astro-E was lost during its launch in February 2000.

JAXA, NASA and the European Space Agency all realized how important the tool was, Miller said, and worked together to essentially refly the Astro-E mission roughly five years later. This time, however, the mission was called Suzaku, named after a phoenix-like mythical bird.

“Suzaku made it into orbit, but its cryogenic system had a leak, so all its coolant leaked into space. Its prime scientific instrument never took actual data,” Miller said. “There was a different camera on board for X-rays, though, and it did really nice work for about 10 years.”

Within months of sunsetting Suzaku, the space agencies launched a third mission to provide the X-ray spectroscopy that the community was seeking. The mission took off as Astro-H in February 2016 and was renamed Hitomi after it entered orbit and deployed its solar panels.

Miller had traveled to Florida for a meeting about Hitomi right around the time disaster struck the mission. A maneuvering error sent Hitomi into an uncontrollable spin.

“It spun so fast that the solar panels flew off,” Miller said.

Less than 40 days after the launch, the space agencies lost contact with Hitomi.

“You could actually go out on the beach in Florida at night and watch it tumble across the sky,” Miller said. “It flickered in a very unique way.”

Before it ended, the Hitomi mission did manage to take what Miller quantified as one and a half scientific observations. That was enough to transform how researchers thought about galaxy clusters, which contain hundreds or thousands of galaxies, he said.

So it’s fair to say that a lot was riding on XRISM when it launched in September 2023. Based on early returns, it sounds like XRISM is equipped to deliver. Miller and a handful of his global colleagues were among the first to see the data that would lead to their new report.

“It was very late in Japan, an odd time in Europe and we were all on Zoom. All of us had trouble finding the words,” Miller said. “It was breathtaking.”

Miller’s original doctoral thesis project was meant to study data from the Astro-E mission, so he’s been invested for more than half his life and virtually his entire science career.

During that time, Hitomi and more successful missions like Chandra have been providing data that have enabled him and others in the field to further our understanding of the cosmos. But the researchers also knew they’d need something like the X-ray calorimeter on board XRISM to make the leaps they’ve been hungry for.

“It’s been difficult at many points, but we kept getting hints about what might be possible,” Miller said. “It’s almost impossible to replicate these environments in earthbound experiments and we’ve been wanting to know a lot of the details of how they really work. I think we’re finally going to make some progress on that.”