Two years of XRISM: X-ray vision on the hottest topics in the Universe

March 30, 2026 cosmos

“Have we achieved the initial science objectives for XRISM after two years?”

The question was posed by Professor Yamaguchi Hiroya, Deputy Project Scientist of the X-Ray Imaging and Spectroscopy Mission (XRISM). It was the close of the first international conference for the XRISM mission. Over 300 participants from 18 different countries had attended the event at Kyoto Terrsa, the same venue that had welcomed the first international conference for XRISM’s predecessor, Suzaku, in 2006.

“I was a graduate student at the first international Suzaku conference,” recalls Yamaguchi. “I never imagined I would be hosting the first international conference for the next mission 19 years later!”

Illustration of the X-Ray Imaging and Spectroscopy Mission, XRISM.

The XRISM space observatory was launched in September 2023 to observe the Universe with X-ray vision. X-rays are emitted by some of most energetic particles in the Universe, from the hot corona of material tumbling into supermassive black holes to vast expanses of hot plasma within clusters of galaxies. XRISM is a joint mission between JAXA and NASA, with international collaboration from ESA and global research institutes. The observatory carries a CCD camera for creating images of the X-ray emission (Xtend) and a flagship spectrometer (Resolve) for measuring the energies of the X-ray photons at unprecedented accuracy.

Evolution of galaxy clusters

The high resolution of the Resolve spectrometer has enabled XRISM to test a long-standing hypothesis regarding the goings-on in the centre of galaxy clusters. Galaxy clusters are the largest structures in the Universe, consisting of hundreds to thousands of galaxies tied together by gravity. In the centre of the cluster, gas between the galaxies is extremely hot and emits X-rays. The continual ejection of incredibly high energy radiation should have caused this dense cluster core region to cool over the billions of years since formation, yet the gas continues to radiate at X-ray emitting temperatures of millions of degrees Celsius. One prominent theory is that the supermassive black hole located at the centre of the brightest cluster galaxy is driving high velocity outflows that shake up the gas to heat the central intracluster medium.

Illustration of a supermassive black hole at a centre of a galaxy and the accompanying outflows. This particular illustration represents the centre of the Seyfert galaxy NGC 4151 based on XRISM observations and past observations.

Resolve is able to directly measure the turbulent gas motion (velocity dispersion) within galaxy clusters. Measurements of the Virgo galaxy cluster have revealed that the velocity dispersion is clearly elevated within the central 50 kpc (160,000 light years), where the brightest galaxy—and its supermassive black hole—is located. With the strongest gas motion within the vicinity of the supermassive black hole, we have clear evidence that the cluster core gas is gaining the energy to maintain high temperatures from this source.

The observed gas motion within the cluster was not always high. Beyond the central region of the cluster, Resolve measured velocity dispersion values lower than most theoretical predictions. Gas in the main body of the cluster (from 50 kpc to about 500 kpc) is predicted to be stirred by mergers and accretion of material falling into the cluster. This expected shake-up has presented observers with a dilemma when estimating the galaxy cluster mass. The majority of the cluster mass is in dark matter, which cannot be directly observed. Instead, scientists calculate the pressure within the cluster based on the temperature of the intracluster gas. If the cluster is not collapsing or expanding, the calculated pressure should be equal to the cluster’s gravity, which is then simply related to the total cluster mass. However, if the intracluster gas is being strongly stirred by incoming material, then the total pressure inside the cluster is from both the gas temperature and the additional kinetic motion. Using only temperature would cause the cluster pressure to be underestimated, thereby underestimating the cluster mass.

The measurements by Resolve of low velocity dispersion values suggest that the non-thermal pressure within the cluster is extremely low, clocking in at only a few percent of the total pressure. Estimates of the galaxy cluster mass based on thermal pressure alone are therefore reasonable.

Energy transport

XRISM also took a closer look at the supermassive black holes themselves. These engines consist of the actual black hole surrounded by a swirling accretion disc of dust and gas, a doughnut shaped dusty torus, and collimated outflows that are ejected perpendicularly to the accretion disc. These outflows are thought to drive galactic-scale winds that then shake up the galaxy cluster core gas.

Illustration of the supermassive black hole PDS 456. High-speed winds with a clumpy structure are being ejected from the vicinity of the black hole.

The outflows from the supermassive black hole are expected to be a smooth, continuous flow. But when the high-resolution power of Resolve observed the supermassive black hole PDS 456, a surprisingly complex structure was seen in the outflows, consisting of at least five bullet-like clumps. A clumpy outflow can carry significantly higher energy compared to a smooth flow, with estimates suggesting that the energy exceeded that in the galactic-scale winds by over 1,000 times! So, if this energy is not driving the winds, where is it going?

One solution is that the clumpy structure is very inefficient at transferring energy to the galaxy gas, which only receives part of the energy output. Alternatively, the outflow may not be continuous but occur in infrequent bursts. This is a new question XRISM has provided to ponder.

Peering deeper into the supermassive black hole system, XRISM looked at the extreme environment of the accretion disc to test Einstein’s Theory of General Relatively. When viewing a rotating disc of gas edge-on, half the disc is moving away from the Earth and its light should become redshifted due to the Doppler effect. The other half of the disc is moving towards the Earth and should become blue-shifted. At normal rotation speeds, this is process is symmetric. However, the incredibly strong gravitational force of the supermassive black hole causes the photons of radiation to lose energy as they struggle to escape. This is expected to redshift all the light to give an asymmetric distribution, with significant redshifted tail.

This result is theoretically predicted by General Relativity, and was hinted at in previously observations by two predecessors to XRISM, the JAXA ASCA and Suzaku X-ray observatories. However, neither space telescope had the resolution required to give a definitive answer. The Resolve spectrometer observed the redshifted tail, and has been able to confirm that the General Relativity effect was indeed at work. This detection allows XRISM to constrain the rotation of the supermassive black hole (watch this space).

Creating the elements of the Universe

Carbon and heavier chemical elements are formed in nuclear fusion reactions within stars. When massive stars end their life, their core collapses and the stars explode as supernovae. Elements that have been fused in the stellar interior are thrown outwards to form new stars, planets, and even life. The resultant cloud of debris is a supernova remnant, and is hot enough to shine in X-rays for tens of thousands of years.

While this process is broadly understood, theoretical models struggle to produce significant abundances of elements with an odd number of protons, such as phosphorus, chlorine or potassium. Yet, these elements are evident in the Universe and are used by biological processes on Earth. Understanding their origin is therefore personal.

Resolve was able to detect the signature of these elements in the supernova remnant, Cassiopeia A. Intriguingly, the elements were concentrated in regions of the remnant where oxygen was abundant, which contradicts traditional models which suggest the elements should be produced in distinct layers within the star. One explanation is that these layers violently mix before the supernova explosion. Such mixing would trigger new fusion reactions, and could form the odd numbered elements far more efficiently than previously expected. Exactly what would cause such mixing is now being debated. It could be that there is strong convection within the star, or perhaps a gravitational interaction from a binary companion could provide a bump.

Illustration of supernova W49B created based on observations from XRISM (X-ray), Palomar (infrared), and VLA (radio).

A big surprise awaited when XRISM looked at a second supernovae remnant, W49B. This supernova remnant is very bright and has previously been well studied. The chemical elements observed in the remnant suggest that W49B is a Type Ia supernova. Rather than forming from a single exploding massive star, Type Ia supernovae occur in binary star systems. One star of the binary pair reaches the end of its life and becomes a white dwarf, a remnant of a star like the Sun which is too low mass to become a supernova. However, the white dwarf begins to accrete mass from its companion star and eventually this creates a thermonuclear explosion. The two processes create supernovae remnants with different element abundances, with Type Ia lacking in elements such as titanium which is found in a deep layer of massive stars.

Despite evidence indicating that W49B was a remnant of Type Ia supernova, Resolve found that the remnant consisted of two outflows to the east and west. This bipolar structure was different from the previously suspected disc shape and moreover, such a structure should not have formed from a Type Ia supernova. Such bipolar flows could be formed during a core-collapse supernova produced by a massive star, but this does not match the abundances of the chemical elements. So… what is W49B? Could this strange structure be produced in a very particular environment, or might this be an entirely new class of supernova?

(An excellent article on this discovery can be found on the XRISM website.)

After two years of operation, the observations from XRISM have confirmed theories, revealed new processes, and raised even more challenges that will progress our understanding of how the Universe is evolving.

“Yes, we did it. The initial science objectives have definitely been completed!” concludes Yamaguchi. “During these first two years, XRISM has also provided even more questions for us to unravel!”

The story of XRISM continues to be written, as the X-ray observatory further explores the strange high-energy Universe for many years to come.

Further information:

XRISM mission website

Related scientific journal papers (external sites):

Gas structure within galaxy clusters: