Tuesday, July 14, 2026

Probing the host galaxy of one of the most distant quasars

Artist's impression of the early quasar with its starforming host galaxy.
© T. Müller, HdA/MPIA



To the point:
  • Super-effective distant quasar hunter: the ESA space telescope Euclid has found a treasure trove of early quasars, including two at record-breaking distances, and is poised to find many more.

  • First look at ordinary early quasars: This is the first time astronomers can examine very early quasars that are ordinary, instead of seeing only the very brightest quasars.

  • A massive, star-forming host galaxy: Follow-up on the galaxy hosting one of those ordinary quasars reveals a massive galaxy forming many stars – a new piece for the puzzle of galaxy formation.



ESA’s space telescope Euclid has opened up a new chapter in the study of early galaxies. New research by Silvia Belladitta (Max Planck Institute for Astronomy, MPIA) and colleagues has followed up on one of the Euclid discoveries to uncover key properties of the host galaxy of one of the earliest supermassive black holes known in the universe.

Bright objects with a dark center

Active galactic nuclei known as quasars are responsible for some of the brightest celestial objects we see in the sky. The “engine” behind that enormous luminosity is matter falling onto a central supermassive black hole – a black hole with masses of millions, billions or an even greater number of solar masses. Such supermassive black holes are found in all but the smallest galaxies. Energy from the 'central engine' influences star formation in a galaxy (in particular the most massive galaxies): by either heating or compressing the gas that is the raw material for new stars, limiting star formation in the first case, enhancing it in the second.

How the first galaxies and their central black holes emerged is a highly active area of research. Finding the earliest quasars and examining their properties and the properties of their host galaxies is an important piece of the puzzle. But targeting the earliest quasars is challenging. Objects that we see as they were in the early universe are necessarily very far away. When light reaching our telescopes today shows us a quasar as it was 13.4 billion years ago, that is because the light needed 13.4 billion years to travel from its source to our telescopes.

Searching for “ordinary” quasars

At such great distances, even intrinsically bright objects like quasars appear rather dim. Easiest to observe are particularly bright specimens – but those, being exceptionally bright, are unlikely to be representative of their more normal siblings. When it comes to the population of quasars, we had so far seen only the tip of the iceberg. This is changing: Euclid’s combination of sensitivity and the ability to scan large areas of the sky at once makes it an ideal search machine for quasars in the early universe. Follow-up observations with ground-based telescopes confirm Euclid’s remarkable quasar-finding power.

Eduardo Bañados, group leader at MPIA and co-lead of the Euclid Quasar Work Package from 2022 to 2025, says: “Seeing Euclid deliver on its potential is immensely satisfying. But more than that, it marks a genuine shift: For the first time, we can study the typical early-universe quasar, not just exceptional outliers. We now have a real window onto how the bulk of the first black holes grew — and how they shaped the galaxies around them."

After only 1.5 years of data-taking, Euclid has more than doubled the number of known early quasars, from nine to 21 (“redshift z>7 quasars”, seen as they were less than 800 million years after the Big Bang). In fact, within a few months, Euclid broke the quasar redshift record not once, but twice!

Probing an extremely distant host galaxy

One refreshingly ordinary early quasar is the one that Belladitta and her team examined more closely. The quasar has the designation EUCL J125308.55+705432.3 (in the usual astronomy fashion, less a name than a detailed sky position). Light we receive today from this quasar was emitted 13 billion years ago, a mere 800 million years after the Big Bang (“z=7.7”). Its UV light amounts to only about 15% the brightness of previous redshift record-holding quasars.

For their follow-up, the astronomers used the NOEMA (NOrthern Extended Millimeter Array) observatory on the Plateau de Bure in the French Alps. NOEMA’s twelve 15-m-antennas act in concert like a single, much larger telescope. The astronomers observed submillimeter light at two carefully chosen wavelengths, each of which traces a different property of the quasar’s host galaxy.

Star formation and dust content

The first type of light is what astronomers call the [CII] line. This kind of light is produced in clouds of molecular gas where new stars are being born. The brightness of this line therefore indicates a galaxy’s star formation rate. The light also allows for a mass estimate: If you have ever heard the way that an emergency vehicle’s siren sound changes as the vehicle passes by, you know how motion influences the wavelength of waves. Applying the same principle in reverse, the way that the [CII] line is shaped allows astronomers to reconstruct the motion of gas in the quasar’s host galaxy, which in turn yields an estimate of its total mass.

The second type of light is thermal radiation from the cold dust in a galaxy. The intensity of this light reveals how much dust is present. The amount of dust is typically associated with the amount of molecular hydrogen, the raw material for star formation – of which this quasar appears to have a lot!

Reconstructing the galaxy’s star-formation rate

Taken together, Belladitta and her colleagues were able to reconstruct key properties of the galaxy that is hosting the quasar. The galaxy is forming stars at a rate of more than 250 solar masses per year – an impressive amount compared to the one solar mass per year of our own Milky Way, but not unexpected given previous finds for less distant quasars. The galaxy’s mass is estimated at around ten billion solar masses, a factor ten less than our own Milky Way. This is consistent with early galaxies that still have a lot of growth ahead of them.

"We found a galaxy that has all the ingredients to build a giant system: it is as massive as the hosts of the brightest early quasars and contains a huge reservoir of molecular gas to fuel intense star formation,” says Silvia Belladitta, a postdoctoral researcher at MPIA. Belladitta, who is the lead author of the study and the new co-leader of the Euclid Quasar Work Package, adds: “This raises an intriguing possibility. UV-faint quasars like EUCL J125308.55+705432.3 may be in a different evolutionary phase than their brighter cousins. Either the black hole is growing more slowly than in the brightest quasars, or else much of its activity is hidden behind thick clouds of dust. Distinguishing between these possibilities will be an exciting challenge for future observations.”

Future plans

For the big picture of galaxy evolution, these are incremental results. But they are pioneering achievements nonetheless, and they point the way forward: with the full 6-year Euclid survey expected to uncover hundreds of additional early quasars of this kind, and with follow-up observations like those of Belladitta and her colleagues providing an ever-larger set of information about star formation rates and galaxy masses, astronomy is steadily building a picture of the earliest galaxies and supermassive black holes in the universe. This will bring the story of the origin of galaxies, and of ourselves, into ever sharper focus.

Background information

The results described here have been published as Belladitta et al. “Euclid: A UV-faint quasar in a highly luminous star-forming host galaxy at z≈7.7” in the journal Astronomy & Astrophysics, doi: 10.1051/0004-6361/202659319. The Euclid quasar search results have been published as D. Yang et al., “Euclid: Discovery of 31 new quasars at 6.6 < z < 7.8” in the journal Astronomy & Astrophysics, doi: 10.1051/0004-6361/202658883.

The MPIA scientists involved are Silvia Belladitta, Eduardo Banados, Fabian Walter, Knud Jahnke, Sarah Bosman, Julien Wolf, and Mischa Schirmer, in collaboration with Roberto Decarli (INAF Observatory, Bologna), Daming Yang (Leiden Observatory), Francesco Guarneri (University of Hamburg) and the rest of the EuclidCollaboration.

Euclid is ESA's mission to characterize Dark Energy and Dark Matter across cosmic time. Launched in 2023, Euclid will survey a third of the sky, recording images for two billion galaxies and precise distances of 50 million galaxies. Euclid's first major data release DR1 will provide data to the world for almost 2000 square degrees in November 2026. The Max-Planck-Institute for Astronomy (MPIA) is a founding member of the Euclid Consortium, a group of now more than 150 institutions across Europe, Canada, Japan, and the USA. During its construction MPIA has contributed hardware for the near-infrared instrument onboard Euclid. Now MPIA scientists are involved in its operation in orbit and are leading Euclid's overall calibration work.




Contacts:

Dr. Markus Pössel
Head of press relations and outreach
Tel:
+49 6221 528-261
Email: pr@mpia.de
Max Planck Institute for Astronomy, Heidelberg

Dr. Silvia Belladitta
Tel:
+49 6221 528-102
Email: belladitta@mpia.de
Max Planck Institute for Astronomy, Heidelberg



Original publication

Silvia Belladitta et al.
Euclid: A UV-faint quasar in a highly luminous star-forming host galaxy at z≈7.7
Astronomy & Astrophysics (2026)


DOI

Daming Yang (Leiden Observatory) et al.
Euclid: Discovery of 31 new quasars at 6.6 < z < 7.8
Astronomy & Astrophysics (2026)


DOI


Monday, July 13, 2026

A cosmic construction project

A galaxy cluster in deep space. It is filled with elliptical galaxies: small, bright white glowing ovals. The two largest elliptical galaxies, left and right of center, are bright cores that radiate light. Unrelated, distant galaxies are scattered around as red smudges and dots.Many of these are stretched out into red arcs and lines by the galaxy cluster’s strong gravity, creating multiple images in places. Numerous spiral galaxies and bright stars appear in the foreground. Credit: ESA/Webb, NASA & CSA, S. Fujimoto



In today’s Picture of the Month from the NASA/ESA/CSA James Webb Space Telescope we are taken on a visit to a building site of significant scale. The project is a galaxy cluster named MACS J0553.4-3342, located in the constellation Columba (the Dove).

MACS J0553.4-3342 is situated at a redshift of 0.412. Redshift is a measure of how much the cluster’s light has been stretched by the expansion of the Universe over the course of its long journey to Webb’s mirrors; this unassuming number tells us that we are seeing MACS J0553.4-3342 as it was 4.4 billion years in the past. But for a galaxy cluster, this is relatively young. In fact, observations with the NASA/ESA Hubble Space Telescope and other telescopes show a cluster still in the process of being built.

MACS J0553.4-3342 is composed of two sub-clusters — roughly equal in mass — that are actively merging. The two subclusters have already slammed through each other and travelled over one million light-years apart, but they will eventually come back together again and again until they finally merge. The construction process is messy, and MACS J0553.4-3342 is filled with extremely hot gas that radiates powerful X-rays. Each subcluster is anchored on an immensely bright and massive elliptical galaxy, which are easily identifiable as the two brightest points in the centre of this scene with the largest glowing halos around them. The many smaller white elliptical galaxies are bound to one of the two subclusters by gravity, and will be incorporated into the final galaxy cluster. This image also features many foreground galaxies — spirals and dusty discs that are unrelated to MACS J0553.4-3342 — and prominent bright stars in our own Milky Way galaxy.

Even mid-way through its construction, the titanic clumps of matter swirling around in this galaxy cluster have built a device that is already very useful for us here on Earth: a gravitational lens. The extreme and concentrated mass in MACS J0553.4-3342 curves light with its gravity, similar to how a glass lens bends and focuses light. In this image you can see prominent orange, stretched-out arcs alongside each of the subclusters. These arcs are images of distant background galaxies, whose light has been warped by the galaxy cluster’s gravitational pull. The arc on the left side, three bright spots joined together, is actually three images of a single background galaxy! A forest of smaller arcs and lines are scattered across the image too; such a fantastic view appears in few other places in the Universe.

Look in the right spot, however, and this galaxy cluster turns from a distorting funhouse mirror into a precision scientific device. The gravitational lensing focuses light, magnifying objects and enhancing their brightness so if they lie in exactly the right place, background galaxies and even individual stars that would have been far too faint and distant to spot will be made visible. By carefully mapping out the mass of the cluster, researchers can reconstruct where and how strongly it distorts light from our point of view, then search for serendipitously-magnified distant objects to study. The arcs we can see in MACS J0553.4-3342 already show a few galaxies from less than a billion years after the Big Bang.

This image, taken with Webb’s Near-Infrared Camera (NIRCam), stems from a survey programme named VENUS (#6882). Astronomers aimed to create a collection of deep, high-quality images of massive galaxy clusters like MACS J0553.4-3342 across a wide range of infrared wavelengths, greatly expanding the area covered by Webb’s sensitive instruments. Researchers can then scour the clusters for distant and faint objects that have been brightened through gravitational lensing, from young galaxies and low-mass black holes to supernova explosions and individual stars. Gravitational lensing has been key to many of Webb’s most dramatic discoveries in recent years, and having many more examples of it allows us to systematically study the distant past and the evolutionary stages of the galaxies, stars and black holes we see today.




Links


Sunday, July 12, 2026

Distant Galaxies: Dead or in Disguise?

This image from the 2-metre Atacama Pathfinder Experiment telescope shows starburst galaxies so distant that their infrared emission has been redshifted to submillimeter wavelengths. Credit: ESO, APEX (MPIfR/ESO/OSO), A. Weiss et al., NASA Spitzer Science Center

Authors: Wenjun Chang et al.
First Author’s Institution: University of California, Riverside
Status: Published in ApJ


Distant galaxies offer a unique window into how stars, gas, and dust evolve over cosmic time. Tracing this evolution requires understanding not only how galaxies form, but also how and when they stop forming stars, a process known as quenching. Understanding how, when, and why galaxies quench is a fundamental question in astrophysics, and one that requires observations of star-forming, quenching, and fully quenched galaxies alike. Unfortunately, one complication is that identifying truly quenched galaxies is challenging: galaxies that appear “dead” may instead be actively forming stars, hidden behind a thick veil of dust.

In today’s article, the authors use observations from the Atacama Large Millimetre/submillimetre Array (ALMA) to investigate five ultramassive galaxies at redshifts, z, between 3 and 4, and ask a deceptively simple question: are these massive red galaxies genuinely quenched, or are they secretly forming stars behind the scenes?

Meet the Suspects: Ultramassive Galaxies at the Edge of Cosmic Noon

The five galaxies in this study are drawn from the Massive Ancient Galaxies at z > 3 NEar-infrared (MAGAZ3NE) survey, which targets some of the most massive galaxies known at early cosmic times. All five have stellar masses exceeding 100 billion solar masses and have been confirmed at z > 3. At these redshifts, we are observing the galaxies as they were when the universe was less than 2 billion years old. This is just before an epoch known as cosmic noon, when star formation across the universe reached its peak.

These galaxies also benefit from extensive multiwavelength observations from a range of observatories, including the ground-based Visible and Infrared Survey Telescope for Astronomy and the Spitzer Space Telescope. By combining imaging across wavelengths from the ultraviolet to the near-infrared, astronomers can measure the “colours” of galaxies and use these colours to infer the galaxies’ star-forming activity.

Galaxies that have quenched their star formation are dominated by older stellar populations, which makes them appear red (hence why they are often referred to as “red and dead” galaxies). However, dust can redden galaxies in a similar way by absorbing blue light and re-emitting it at longer wavelengths — meaning that a dusty, star-forming galaxy can easily masquerade as a quenched one. To uncover any hidden star formation, the authors turn to ALMA to search for far-infrared dust emission. The sample of galaxies investigated with ALMA is shown in Figure 1.

Figure 1: UVJ colour–colour diagram, which uses galaxy colours in the ultraviolet (U), visible (V), and near-infrared (J) to identify quenched galaxies. The five ultramassive galaxies (UMGs) studied here (filled cyan circles) lie firmly in the quenched region (QG), consistent with a lack of ongoing star formation. Crosses indicate galaxies undetected in ALMA dust emission, while other massive galaxies at similar redshifts are shown in grey for comparison. Credit: Chang et al. 2026

ALMA on the Scene

ALMA observes light at sub-millimetre wavelengths, which at these redshifts traces emission from star-forming regions that are obscured by dust. Of the five ultramassive galaxies in this sample, only one is detected with ALMA. Even when the remaining four galaxies are stacked together, no dust emission is recovered, indicating that if any dust is present, it must be extremely faint.

To better quantify what these ALMA non-detections imply, the authors perform spectral energy distribution fitting (see a recent overview bite on spectral energy distribution fitting) using the Code Investigating GALaxy Emission, or CIGALE, a code that enforces energy balance between absorbed starlight and dust emission to estimate physical properties such as a galaxy’s star formation rate and dust content. With the ALMA constraints included, all five galaxies are found to lie more than 10 times below the star-forming main sequence. Even the single ALMA-detected galaxy remains formally quenched, showing only weak residual star formation.

In other words, these galaxies really are dead (or at least extremely dormant).

Extremely Dust-Poor Galaxies

The spectral energy distribution fitting also allows the authors to measure how much dust these galaxies contain relative to their stellar mass. This ratio provides a simple but powerful way to assess how much interstellar material remains in a galaxy — and therefore how much fuel is left for future star formation.

Three of the five ultramassive galaxies have ratios of Mdust/Mstar < 10-4 (Figure 2), placing them among the most dust-poor quenched galaxies confirmed at z > 3. The lone galaxy detected by ALMA contains slightly more dust, with Mdust/Mstar = 10-3, but even this is far below what would be expected for an actively star-forming galaxy. For comparison, typical star-forming galaxies at similar stellar masses host more than 100 times more dust.

Figure 2: The ratio of dust mass to stellar mass versus redshift for massive quenched galaxies (QGs). This quantity measures how dust rich a galaxy is compared to its stellar mass. The ultramassive galaxies in this study (cyan pentagons) fall well below the dust content expected for star-forming galaxies (solid blue line), highlighting their extreme dust deficiency. Adapted from Chang et al. 2026


These results raise important questions about how galaxies can become ultramassive, quenched, and nearly dust-free within the first two billion years of cosmic history.

For now, ALMA has delivered a clear answer to the question of “dead or in disguise?”: at least some candidate ultramassive galaxies in the early universe really are quenched, and they are strikingly dust poor. By ruling out the dusty impostor scenario, this study shows that deep ALMA observations can cleanly distinguish genuinely quenched galaxies from dusty star-forming ones, even at the highest stellar masses and earliest cosmic times. How these galaxies lost their dust remains an open question, but one thing is clear: by the time cosmic noon arrived, some galaxies had already finished forming stars and quietly faded into dormancy.

Original astrobite edited by Viviana Cáceres.




About the author, Lucie Rowland:

I’m a fourth (and final!) year PhD student at Leiden Observatory in the Netherlands, studying massive, star forming galaxies in the early universe with ALMA and JWST. It’s a really exciting time to be interested in astronomy, so I hope to make groundbreaking new research more accessible!



Editor’s Note: Astrobites is a graduate-student-run organization that digests astrophysical literature for undergraduate students. As part of the partnership between the AAS and astrobites, we occasionally repost astrobites content here at AAS Nova. We hope you enjoy this post from astrobites; the original can be viewed at    astrobites.org.


Saturday, July 11, 2026

NSF VLA Maps a Hidden Hydrogen Shell Around the Orion Nebula

Radio emission from neutral hydrogen atoms in the direction of the Orion Nebula, the most nearby regions of high-mass star formation. The red colors show the 21-cm emission from hydrogen, resolved for the first time at this level of detail by observations from the Neutral Atomic Hydrogen in the Solar Neighborhood (NeAtHood) project, led by Juan Diego Soler from the University of Vienna. The cyan colors show the emission from warm interstellar dust in near-infrared light. Credit: Juan D. Soler, University of Vienna, with data from the NRAO's Jansky VLA and NASA's Wide-field Infrared Survey Explorer (WISE).
Hi-Res File


New view of a familiar nebula
The Orion Nebula is perhaps the best known nebula, yet new discoveries continue to emerge from observations across all wavelengths of the electromagnetic spectrum. Long known to be a region of active star formation, astronomers using the U.S. National Science Foundation Very Large Array (NSF VLA) have resolved the emission from neutral atomic hydrogen that elucidates how the young stars in Orion are shaping their surrounding neighborhood.

A team of astronomers led by Juan D. Soler of the University of Vienna used the NSF VLA, operated by the U.S. National Science Foundation’s National Radio Astronomy Observatories (NSF NRAO), to obtain high-resolution observations of the emission from neutral hydrogen atoms (HI) at 21 centimeters wavelength. Neutral atomic hydrogen, or H I, is traced by faint radio emission at a wavelength of 21 centimeters. Mapping that emission at high angular resolution is challenging, but the NSF VLA’s interferometric design makes it possible to resolve the structure of nearby star-forming regions.The NSF VLA, therefore, proved to be the best possible instrument for the task, Soler explains. “The NSF VLA is a very unique instrument. It is fundamental, offering the best resolution that we can get in HI from the northern hemisphere. We cannot do this with any other instrument.”

Measuring the bubble directly
When Soler and his team looked deep within the Orion Nebula, they focused on a previously identified expanding bubble formed by young stars. These past observations used tracers such as CII as a proxy for the hydrogen and offered an estimate of the mass associated with star formation. Because Soler’s team was able to observe the HI directly, their data provided a more direct estimate of the bubble’s mass,improving measurements by a factor of ten. “Measuring mass is fundamental,” Soler says, “because it tells us how efficiently these newly formed stars shape their environment with wind and radiation.”

Furthermore, the data obtained by Soler’s team also map the neutral atomic hydrogen in the vast molecular clouds within the Orion Nebula. Soler describes this interrelationship: “Talking about molecular clouds without talking about HI, is like talking about islands without ever mentioning the sea. It turns out that as we’re resolving the sea, we’re finding phenomena like this bubble that are shaping and connecting those molecular clouds. We imagine them as separate objects, not as if they were islands, completely isolated; in fairness, they’re more like archipelagos.”

First result from NeAtHood
These results, published in Astronomy & Astrophysics, are the first within a larger project called Neutral Atomic Hydrogen in the Solar System Neighborhood (NeAtHood), which aims to continue observing other nearby molecular clouds within star-forming regions visible from the northern hemisphere to produce arcminute-resolution HI maps. Soler looks to the possibility of future observations both within this program and beyond, saying, “[The bubble] is the kind of thing that should be there, but we were not expecting to see this so clearly. So now I wonder, what other surprises are hiding in the data? And in the future, the Next-Generation VLA (ngVLA) is going to target even more distant regions in the Milky Way.”




Links: Scientific Paper



Press Contacts:

Corrina Jaramillo Feldman
Sr. Public Information Officer

Email | Phone



About NRAO

The National Radio Astronomy Observatory is a major facility of the U.S. National Science Foundation, operated under cooperative agreement by Associated Universities, Inc.)


Hidden Jet from a “Missing-Link” Black Hole Lights Up the Radio Sky

Artist's conception illustrating the aftermath of an intermediate-mass black hole tearing apart a passing star, resulting in an accretion disk and narrow relativistic jet (top left). The dotted line indicates our line of sight from Earth. The jet's off-axis afterglow only became visible once the expanding radio emission (bottom right) had grown wide enough to sweep into our line of sight, causing that emission to brighten dramatically years after the initial event. Credit: NSF/AUI/NSF NRAO/M.Weiss
. Hi-Res File



Astronomers using the U.S. National Science Foundation Very Large Array (NSF VLA) have detected an extraordinary burst of radio light from a rare cosmic event in which an intermediate-mass black hole tears apart a star, revealing what appears to be the off-axis afterglow of a powerful jet.

Unusual Observations of AT2019ijn
The event, known as AT2019ijn, first appeared as a bright blue flash in optical surveys, rising to peak brightness in just a few days before fading much more slowly than similar transients usually do. When astronomers later examined radio observations, they found something even more unusual: the radio emission kept brightening for nearly two years and reached a luminosity far beyond that seen in typical stellar explosions at similar phases, followed by a slow decay over at least four years.

The researchers concluded that the most likely explanation is a tidal disruption event, which happens when a star strays too close to a black hole and is pulled apart by gravity. In this case, the fast rise in the optical brightness indicates an intermediate-mass black hole, a long-sought class that falls between stellar-mass black holes formed by collapsing stars and the supermassive black holes found in the centers of galaxies. These middleweight black holes have been difficult to find, and astronomers have been eager for new ways to identify them.

AT2019ijn offers one such path: if an intermediate-mass black hole launches a jet that is not aimed directly at Earth, the event may look modest at first, then become dramatically brighter in radio light later as the jet slows and its afterglow emission spreads into view. That delayed brightening is one of the most striking features of this discovery. At 3 gigahertz, the radio signal reached a luminosity more than 100 times brighter than radio emission seen from known fast blue optical transients or supernovae at similar stages.

Multi-Facility Observations and Modeling
To piece together the event, the team combined optical survey data with radio observations from the NSF VLA, including the Very Large Array Sky Survey, and additional measurements from ASKAP in Australia and the upgraded Giant Metrewave Radio Telescope in India. That broad radio coverage let the researchers track how the signal changed over time and test models for an expanding outflow powered by a tidal disruption event. Their modeling suggests the radio emission came from material moving at a significant fraction of the speed of light. The data are best explained by a narrow relativistic jet viewed from well off to the side, rather than head-on, which naturally accounts for why the radio flare appeared so late.

Scientific Significance
This discovery is especially significant because it expands the way astronomers can search for hidden black holes and the extreme jets they launch. It also suggests that some unusual optical transients may be part of a broader family of black-hole-powered events that have been missed because their radio peaks arrive long after the initial flash. As new sky surveys repeatedly scan the heavens in both visible light and radio waves, astronomers expect to find more events like AT2019ijn. Each new detection could help reveal how intermediate-mass black holes form, how often they tear apart stars, and under what conditions they produce powerful jets.

The results are reported in a paper accepted for publication in The Astrophysical Journal Letters. You can read the full publication at the included link.




Links: Scientific Paper



Press Contacts:

Corrina Jaramillo Feldman
Sr. Public Information Officer

Email | Phone



About NRAO

The National Radio Astronomy Observatory is a major facility of the U.S. National Science Foundation, operated under cooperative agreement by Associated Universities, Inc.)


Friday, July 10, 2026

NASA's Chandra Releases 'Red, White, and Blue' Universe for US 250th

Cassiopeia A - NGC 3603 - NGC 4736 (M94) - ZwCl 0024+1652
Credit: NASA/CXC/SAO




In celebration of the 250th birthday of the United States, NASA has unveiled four cosmic images from its Chandra X-ray Observatory rendered in red, white, and blue that represent the wonders of the universe the agency explores. The images are accompanied by a trio of new sonifications — a technique that translates astronomical data into sounds.

The image set begins with Cassiopeia A in the top panel, where X-rays from Chandra (represented in blue and purple) have been combined with an infrared image from NASA’s James Webb Space Telescope (red and white). Chandra’s X-ray vision reveals the blast wave that tore through the star, as well as elements in the debris field like iron, calcium, and oxygen. Webb’s infrared data also shows the expanding shell of material from the explosion and cosmic dust throughout the remnant.

In the bottom row, the first image on the left is the nebula NGC 3603, which contains a massive cluster of stars and is located in the Milky Way galaxy. This new composite image contains Chandra’s X-ray data (red and white) and shows diffuse emission near the galaxy’s center along with point-like X-ray sources throughout the middle of the image. Optical, infrared, and ultraviolet light from NASA’s Hubble Space Telescope (red-orange, green, blue, and yellow) reveal stars in the center of the image and dust and gas toward the bottom. The combined layering of the colors makes this nebula and the stars forming within it appear primarily red, white, and blue, with X-rays showing the sparkling lights of young stars.

The middle panel of the bottom row is a new look at the galaxy NGC 4736, also known as Messier 94. In this image, X-rays of different wavelengths from Chandra (red, orange, and blue) are layered with a visible light image from astrophotographers using their telescopes on the ground (red, green, and blue). Messier 94 is a spiral galaxy with a bright inner ring around it, called a starburst ring, where new stars are forming, perhaps fueled by gas driven in the unique oval-shaped structure seen here.

The final image in this red, white, and blue quartet features ZwCl 0024+1652. This is a distant galaxy cluster in which astronomers have found evidence for dark matter by using specially processed data from Hubble (blue). Another image from Hubble reveals the individual galaxies in the cluster (appearing as yellow and white). X-ray data from Chandra shows the enormous reservoir of superheated gas that pervades this galaxy cluster (red) with much more mass than all the galaxies taken together.

New sonifications of the three images along the bottom row of this mosaic are also available, allowing listeners to experience data through sound.

The translation of NGC 3603 into sound begins with a left to right scan, where the brightnesses of the sources once again dictate volume. Chandra’s observations of compact sources sprinkled throughout the galaxy are heard as piano notes, while the diffuse X-ray emission is mapped to a range of audio frequencies. The Hubble optical data is played as sustained tones and acoustic guitar harmonics.


In the sonification of NGC 4736, the radar-like scan moves clockwise, and the brightness of the sources dictates the volume of the sounds. X-rays from Chandra have been turned into wind-like sounds that follow the shape of the X-ray emission. Neutron stars and stellar-mass black holes (known as “compact sources”) detected by Chandra are mapped to pitched tones on a glass marimba. Optical data from ground-based observations is mapped to musically pitched tones, creating a low drone, while stars and background galaxies are heard as a soft piano.


For ZwCl 0024+1652, the sonification begins as a circle on the outside of the image and moves inward. The volume is linked to the brightness of the data, reaching one peak as the circle passes over the dark matter detected by inference from Hubble optical observations and another as it reaches the core. The background stars are heard as a swelling glockenspiel-like sound, and the galaxies are played on a piano. Chandra’s X-rays, which dominate the center of the galaxy cluster and reveal superheated gas, are represented by airy synthesizer notes.


The sonification program is led by the Chandra X-ray Center (CXC) and included as part of NASA's Universe of Learning program. The collaboration was driven by visualization scientist Kimberly Arcand (CXC), Matt Russo, astrophysicist; and Andrew Santaguida, musician, SYSTEM Sounds project; along with Christine Malec, consultant. Previously released sonifications of data from from Cassiopeia A can be found at chandra.si.edu/sound.

NASA's Marshall Space Flight Center in Huntsville, Alabama, manages the Chandra program. The Smithsonian Astrophysical Observatory's Chandra X-ray Center controls science operations from Cambridge, Massachusetts, and flight operations from Burlington, Massachusetts.




Visual Description:

In celebration of the 250th birthday of the United States, this release includes a series of images featuring four wonders of the universe, rendered in red, white, and blue. The images contain X-ray data from the Chandra X-ray Observatory, optical and infrared data from the Hubble Space Telescope and the James Webb Space Telescope, as well as ground-based telescopes.

The main image set features composite images of the four individual objects; Cassiopeia A, NGC 3603, M94/NGC 4736, and ZwCl 0024+1652.

Cassiopeia A occupies the top panel of the frame, significantly larger than the other images in the set. The cloudy blast-wave of the supernova remnant is ring-like in shape, streaked with veins of iron, calcium, and oxygen. Here, presented in red, white, and blue, the remnant resembles an electrified donut, crackling with marbled veins of strawberry and blueberry icing.

At our lower left of the image set is the nebula NCG 3603, which contains a massive cluster of stars on the other side of the Milky Way galaxy. Here, a tight cluster of neon red and white stars packs the center of the image, dissipating as it reaches the outer edges of the panel. Sweeping in at the lower corners of the image are hazy blue clouds resembling sheets of gauze.

Centered at the bottom of the image set is the galaxy NGC 4736, also known as Messier 94 (M94). Here, the spiral galaxy is seen face on, with concentric pale violet cloud rings flecked with scores of stars in white, pale blue, soft red, and golden yellow. The inner ring of the galaxy is bright, and rosy yellow in color. This is a starburst ring, where new stars are forming.

At our bottom right of the image set is the distant galaxy cluster ZwCl 0024+1652. The image is packed with streaks and specks in golden yellow and brilliant white. Upon close inspection, each streak and speck is revealed to be an individual galaxy, some with discernible spiral shapes. At the center of the image is a round pool of bright red light, surrounded by royal blue haze. The red light represents X-ray observations by Chandra, which reveal an enormous reservoir of superheated gas pervading the cluster. The blue haze represents specially-processed data from Hubble, suggesting evidence of dark matter.

This release also includes new sonifications of the three images presented in the bottom row of this data set, allowing listeners to experience the data through sound.



Fast Facts for Cassiopeia A:

Credit: X-ray: NASA/CXC/SAO; IR: NASA/ESA/CSA/STScI; Image Processing: NASA/CXC/SAO/L. Frattare and K. Arcand
Release Date: June 30, 2026
Scale: Image is about 8 arcmin (25.5 light-years) across.
Category:
  Supernovas & Supernova Remnants
Coordinates (J2000): RA: 23h 23m 26.7s | Dec: +58° 49' 03.00"
Constellation:
Cassiopeia
Observation Date(s): Nine observations in 2004: Feb 8, Apr 14, 18, 20, 22, 25 28, May 1, 5
Observation Time: 277 hours and 58 minutes (11 days 13 hours 58 minutes)
Obs. IDs: 4634-4639, 5196, 5319-5320
Instrument:
ACIS
Color Code: X-ray: blue and red; Infrared: red and white
Distance Estimate: About 11,000 light-years from Earth



Fast Facts for NGC 3603:

Credit: X-ray: NASA/CXC/SAO; Optical/IR/UV (Hubble): NASA/ESA/CSA/STScI/AURA; Image Processing: NASA/CXC/SAO/L. Frattare and K. Arcand
Release Date: June 30, 2026
Scale: Image is about 3 arcmin (17 light-years) across.
Category:
Normal Stars & Star Clusters
Coordinates (J2000): RA: 11h 15m 9.09s | Dec: -61° 16' 17.0"
Constellation:
Carina
Observation Date(s): Five observations from May 2000 to October 2011
Observation Time: 138 hours 8 minutes (5 days 18 hours 8 minutes)
Obs. IDs: 633, 12328-12330, 13162
Instrument:
ACIS
Color Code: X-ray: red and white ; Infrared: red and yellow; Ultraviolet: green, blue, and white
Distance Estimate: About 20,000 light-years from Earth




Fast Facts for NGC 4736 (M94):

Credit: X-ray: NASA/CXC/SAO; Optical:Brian Brennan and Remi Lacasse; Image Processing: NASA/CXC/SAO/L. Frattare and K. Arcand
Release Date: June 30, 2026
Scale: Image is about 17 arcmin (94,000 light-years) across.
Category:
Normal Galaxies & Starburst Galaxies
Coordinates (J2000): RA: 12h 50m 53.1s | Dec: +41° 07' 13.7"
Constellation: Canes Venatici
Observation Date(s): May 13, 2000
Observation Time: 13 hours 50 minutes
Obs. IDs: 808
Instrument:
ACIS
Color Code: X-ray: red, green, and blue; Optical: red, green, and blue
Distance Estimate: About 19 million light-years from Earth



Fast Facts for ZwCl 0024+1652:

Credit: X-ray: NASA/CXC/SAO; Optical and Dark Matter: NASA/ESA/M.J. Jee; Image Processing: NASA/CXC/SAO/L. Frattare
Release Date: June 30, 2026
Scale: Image is about 3.3 arcmin (9,100 light-years) across.
Category:
Groups & Clusters of Galaxies
Coordinates (J2000): RA: 00h 26m 34.5s | Dec: +17° 09′ 44.0"
Constellation:
Pisces
Observation Date(s): 3 Observations from Sep, 2000 to Aug, 2016
Observation Time: 29 hours 30 minutes (1 day 5 hours 30 minutes)
Obs. IDs: 929, 7717, 18458
Instrument:
ACIS
Color Code: X-ray: red; Optical: red, green, and blue; Dark Matter: blue
Distance Estimate: About 9.5 million light-years from Earth


Thursday, July 09, 2026

VLT image of interstellar comet 3I/ATLAS (18 January 2026)

PR Image eso2608a
VLT image of interstellar comet 3I/ATLAS (18 January 2026)

PR Image eso2608b
VLT spectrum of interstellar comet 3I/ATLAS

PR Image eso2608c
VLT image of interstellar comet 3I/ATLAS (18 February 2026)



Videos

3I/ATLAS likely formed in the outskirts of an old star system | ESO News
PR Video eso2608a
3I/ATLAS likely formed in the outskirts of an old star system | ESO News

VLT time-lapse of insterstellar comet 3I/ATLAS
PR Video eso2608b
VLT time-lapse of insterstellar comet 3I/ATLAS

Trajectory of interstellar comet 3I/ATLAS
PR Video eso2608c
Trajectory of interstellar comet 3I/ATLAS



Astronomers have used the European Southern Observatory's Very Large Telescope (ESO's VLT) to study the composition of 3I/ATLAS, the brightest interstellar object ever seen, in detail. By measuring specific chemical fingerprints — the first observations of this kind for a comet that formed outside the Solar System — they found that 3I/ATLAS likely originated in the outskirts of an old star system. The findings shine new light on the formation history of this comet, indicating that it may be much older than the Sun.

Interstellar comets are icy objects formed around a star other than the Sun that occasionally wander into our Solar System. "They are sort of fossils from a planetary formation process that happened very far away, but that we get the chance to study from much closer," says astronomer Cyrielle Opitom, a researcher at the University of Edinburgh, United Kingdom. Together with Jean Manfroid and Damien Hutsemékers of the University of Liège, Belgium, Opitom led a study of 3I/ATLAS published today in Nature Astronomy.

3I/ATLAS is the third interstellar object ever discovered, after 1I/ʻOumuamua and 2I/Borisov. It was found as it was approaching the Sun, spending enough time in our Solar System for astronomers to study it in detail. While it was difficult to measure the composition of the first two interstellar objects — in the first astronomers didn’t detect gas and the second was too faint — this was not the case for 3I/ATLAS. Thanks to the object's unprecedented brightness, Opitom, Manfroid, Hutsemékers and their team were able to measure the comet's isotopic ratios: the relative amounts of different forms of the same element.

Using the UVES instrument on ESO's VLT, the team measured ratios of carbon and nitrogen isotopes in cyanide molecules present in the gas around the comet. These ratios are known to be a good indicator of a comet’s origin, as they are very sensitive to the physical conditions in the formation environment and are not expected to change much as the comet travels on through space.

Unlike comets from our Solar System, this interstellar visitor carries unusually high carbon and nitrogen isotopic ratios,” explains Aravind Krishnakumar, a researcher at the University of Liège and co-author on the new study. A similar study led by Martin Cordiner at the NASA Goddard Space Flight Center, US, that was published late last month in Nature, found a similar isotopic ratio of carbon, as well as elevated levels of deuterium, also called heavy hydrogen [1]. The study used data from the James Webb Space Telescope, a joint project of the US, European and Canadian space agencies.

Overall, the findings by Opitom’s team indicate that the comet likely formed in the outer regions around an old, ‘low-metallicity’ star. A low-metallicity star is one with few elements heavier than helium in its composition, that is thought to have formed when the Universe was much younger — and less chemically rich — than it is now. The team suspects that 3I/ATLAS therefore originated around a star much older than the Sun. “3I/ATLAS is a really exciting opportunity to probe the composition of another planetary system, one that formed long before our Sun and Solar System even existed," says co-author Rosemary Dorsey, a researcher at the University of Helsinki, Finland. Evidence from the studies by the different teams points to 3I/ATLAS being more than twice as old as the Sun.

As 3I/ATLAS moves away from the Sun and gets progressively fainter, its observations at the VLT are also nearing their end. ESO's upcoming Extremely Large Telescope (ELT) will allow similar measurements for future interstellar objects, including those less bright than 3I/ATLAS. "The field of interstellar objects is still very new, and we do not really know what to expect. Every time a new one is discovered, we have new surprises," Opitom concludes.

Source: ESO/News



Notes

[1] A team lead by Salazar-Manzano and Paneque-Carreño used the Atacama Large Millimeter/submillimeter Array (ALMA), in which ESO is a partner, to measure deuterated (or semi-heavy) water in 3I/ATLAS. They also found elevated levels of this type of water compared to those found in Solar System comets.



More information

´´This research was presented in a paper to appear in Nature Astronomy (doi:10.1038/s41550-026-02921-7).

The team is composed of C. Opitom (Institute for Astronomy, University of Edinburgh, Royal Observatory, UK [Edinburgh]), J. Manfroid (STAR Institute, University of Liège, Belgium [STAR]), D. Hutsemékers (STAR), E. Jehin (STAR), M. M. Knight (Volgenau Department of Physics, United States Naval Academy, Annapolis, MD, USA), K. Aravind (STAR), L. Ferellec (Faculty of Science and Engineering, Northumbria University, Newcastle, UK), D. Bodewits (Physics Department, Edmund C. Leach Science Center, Auburn University, AL, USA), V. V. Guzmán (Instituto de Astrofísica, Pontificia Universidad Católica de Chile, Santiago, Chile), M. Cordiner (Department of Physics, Catholic University of America, Washington, DC, USA and Astrochemistry Laboratory, NASA Goddard Space Flight Center, Greenbelt, MD, USA), R. C. Dorsey (Department of Physics, University of Helsinki, Finland), F. La Forgia (Department of Physics and Astronomy, University of Padova, Italy), M. Lippi (INAF - Osservatorio Astrofisico di Arcetri, Firenze, Italy), B. P. Murphy (Edinburgh), C. Snodgrass (Edinburgh).

The European Southern Observatory (ESO) enables scientists worldwide to discover the secrets of the Universe for the benefit of all. We design, build and operate world-class observatories on the ground — which astronomers use to tackle exciting questions and spread the fascination of astronomy — and promote international collaboration for astronomy. Established as an intergovernmental organisation in 1962, today ESO is supported by 16 Member States (Austria, Belgium, Czechia, Denmark, France, Finland, Germany, Ireland, Italy, the Netherlands, Poland, Portugal, Spain, Sweden, Switzerland and the United Kingdom), along with the host state of Chile and with Australia as a Strategic Partner. ESO’s headquarters and its visitor centre and planetarium, the ESO Supernova, are located close to Munich in Germany, while the Chilean Atacama Desert, a marvellous place with unique conditions to observe the sky, hosts our telescopes. ESO operates three observing sites: La Silla, Paranal and Chajnantor. At Paranal, ESO operates the Very Large Telescope and its Very Large Telescope Interferometer, as well as survey telescopes such as VISTA. Also at Paranal, ESO will host and operate the south array of the Cherenkov Telescope Array Observatory, the world’s largest and most sensitive gamma-ray observatory. Together with international partners, ESO operates ALMA on Chajnantor, a facility that observes the skies in the millimetre and submillimetre range. At Cerro Armazones, near Paranal, we are building “the world’s biggest eye on the sky” — ESO’s Extremely Large Telescope. From our offices in Santiago, Chile we support our operations in the country and engage with Chilean partners and society.



Links



Contacts:

Cyrielle Opitom
School of Physics and Astronomy, University of Edinburgh
Edinburgh, United Kingdom
Tel: +44 (0)131 668 8350
Email:
copi@roe.ac.uk

Aravind Krishnakumar
Space sciences, Technologies & Astrophysics Research (STAR) Institute, University of Liège
Liège, Belgium
Email:
aravind139@gmail.com

Rosemary Dorsey
University of Helsinki
Helsinki, Finland
Email:
rosemary.dorsey@helsinki.fi

Bárbara Ferreira
ESO Media Manager
Garching bei München, Germany
Tel: +49 89 3200 6670
Cell: +49 151 241 664 00
Email:
press@eso.org


Wednesday, July 08, 2026

The Environment Around a Supermassive Black Hole

Artist's impression of the innermost regions around a supermassive black hole, showing an accretion disk visually distorted by gravity surrounding the event horizon, and powering an outflow of material. Image credit: CfA/M. Weiss.
Download Image

During the past week, NuSTAR observed the nearby active galactic nucleus (AGN) I Zwicky 1 in coordination with the JAXA/ESA/NASA’s XRISM and ESA’s XMM-Newton X-ray observatories. I Zwicky 1 is a unique AGN from which we can learn a lot about the fundamental physics at work as material spirals into a black hole, and the processes by which supermassive black holes grow and are able to have a profound impact on their host galaxies by AGN feedback. In this AGN, we observe X-rays reflecting off the innermost regions of the accretion disk, allowing us to probe the extreme environment just outside the event horizon of the black hole. In addition, I Zwicky 1 is seen to launch an ultrafast outflow: a wind from the inner accretion disk reaching velocities up to 30% of the speed of light. These outflows carry significant energy into their host galaxies and understanding how they are launched is an important step towards understanding AGN/host galaxy feedback. I Zwicky 1 is often seen to launch X-ray flares originating in the corona, and the outflows are seen to evolve in response to these flares. Through these observations, important new insights are expected into the structure of the accretion disk around a rapidly growing black hole, the launching mechanism of the ultrafast outflows, and the connection between these outflows and the innermost regions of the accretion disk and the corona.
Author: Dan Wilkins (Research Assistant Professor, The Ohio State University)



Tuesday, July 07, 2026

Faint galaxy around Andromeda discovered

Location of And XXXVI (marked in red) within the Pan-Andromeda Archaeological Survey (PAndAS). And XXXVI is located approximately 119 kpc in projected distance from Andromeda (M31). Credit: Sakowska et al. 2026.
Original size [904 x 642, 190 KB]



June 29, 2026 // A new ultra-faint dwarf galaxy has been discorved in the vicinity of Andromeda (M31), the Milky Way’s large neighbouring galaxy. The study suggests that the galaxy named And XXXVI is one of the faintest satellite galaxies discovered around Andromeda to date.

Ultra-faint dwarf galaxies are among the smallest and dimmest galaxies known. Formed during the earliest stages of the Universe, they are considered fossil records of the first galaxies and are thought to be dominated by dark matter. As such, they provide a unique window into galaxy formation in the early Universe and offer valuable tests of dark matter models.

“Our study suggests that And XXXVI is an extremely old galaxy, around 12.5 billion years old, and remarkably poor in heavy elements,” says Joanna Sakowska, researcher at Researchers at the Instituto de Astrofísica de Andalucía (IAA-CSIC) and lead author of the study. “However, observations with space telescopes such as Hubble will be needed to determine its distance, age and chemical composition with greater precision.” The results have been published in the journal Astronomy & Astrophysics (A&A).

Located approximately 2.5 million light-years from Earth, the Andromeda Galaxy is the closest giant spiral galaxy to the Milky Way. Like our own galaxy, it is surrounded by numerous dwarf satellite galaxies that orbit under its gravitational influence.

"The discovery of Andromeda XXXVI offers a new perspective on the smallest galaxies in the universe. Within the framework of the standard cosmological model, the so-called Lambda Cold Dark Matter model (ΛCDM), we expect galaxies like Andromeda to be surrounded by hundreds of such small companions—yet many of them have remained hidden until now due to their low luminosity,” says Isabel Santos Santos from the Leibniz Institute for Astrophysics Potsdam (AIP), a co-author of the study. “Each newly discovered ultra-faint dwarf galaxy helps us explore the limits of galaxy formation and put our cosmological models to the test."

“We currently know of around 40 dwarf satellite galaxies around Andromeda, of which only about 15 are classified as ultra-faint,” explains Sakowska. “Each new discovery, such as Andromeda XXXVI, is important because it suggests that we may still be seeing only the tip of the iceberg of a much larger population of extremely faint galaxies.”

Andromeda XXXVI was first identified by the astrophotographer and amateur astronomer Giuseppe Donatiello while examining images from the Pan-Andromeda Archaeological Survey (PAndAS), carried out with the Canada-France-Hawaii Telescope (CFHT). The object appeared as a faint diffuse feature in which individual stars could already be distinguished. It was subsequently included it in a list of candidate galaxies for further investigation.

The team secured Director's observing Time on the Gran Telescopio Canarias (GTC) where they used the OSIRIS+ instrument to obtain much deeper images. These observations allowed them to distinguish individual stars within the galaxy's faint, diffuse light. However, Andromeda XXXVI proved to be an exceptionally faint object: the research team was only able to identify about 46 stars associated with it.




The Leibniz Institute for Astrophysics Potsdam (AIP) is dedicated to astrophysical questions ranging from the study of our sun to the evolution of the cosmos. The key areas of research focus on stellar, solar and exoplanetary physics as well as extragalactic astrophysics. A considerable part of the institute's efforts aims at the development of research technology in the fields of spectroscopy, robotic telescopes, and e-science. The AIP is the successor of the Berlin Observatory founded in 1700 and of the Astrophysical Observatory of Potsdam founded in 1874. The latter was the world’s first observatory to emphasize explicitly the research area of astrophysics. The AIP has been a member of the Leibniz Association since 1992.


Monday, July 06, 2026

NASA's Chandra Examines Milky Way at Arms' Length





  • The outer spiral arms of the Milky Way galaxy may be farther away than scientists previously thought.

  • This discovery was made by measuring light echoes from distant gamma-ray bursts using NASA’s Chandra and ESA’s XMM-Newton.

  • Even a small change in the distance to these arms has a significant impact on our understanding of the Milky Way’s structure.

  • While this technique is powerful, gamma-ray bursts are rare so it may be difficult to use them to measure distances to other spiral arms.



The graphic illustrates a new result that indicates the outer spiral arms in the Milky Way galaxy may reach wider than previously thought, according to data from NASA’s Chandra X-ray Observatory and ESA’s XMM-Newton. This finding could lead astronomers to adjust their understanding of our home galaxy’s structure and is described in our latest press release.

The sequence begins with an artist’s concept showing the Milky Way galaxy as seen from above with the estimated positions of spiral arms based on previously-obtained data from various telescopes. The second artist’s concept shows new positions of the two spiral arms most distant from the center of the galaxy, that have been adjusted based on X-ray data from Chandra and XMM-Newton.

Illustration Showing Updated Spiral Arm Positions
An artist’s concept showing the Milky Way galaxy as seen from above, with the estimated positions of spiral arms based on previous data, in blue. Overlaid on this is an updated view of the Milky Way showing different positions for the two outermost spiral arms, shown in red and bordered by dashed lines. Both arms may be more distant than previously thought, based on newly processed X-ray data from Chandra and XMM. Credit: NASA/CXC/SAO/M.Weiss

A team of researchers determined the distances to these spiral arms by studying rings around gamma-ray bursts (GRBs), some of the brightest bursts of light in the universe. GRBs happen when massive stars collapse or neutron stars merge, and they are located at enormous distances — well beyond the confines of our galaxy. The distance measurement technique capitalized on the phenomenon of light echoes, where the light from the GRB bounced off intervening dust clouds in the spiral arms. The diameters of the rings in X-rays give the distances to Earth, with larger rings being generated by dust clouds closer to us.

A composite image shows one set of light echoes used in the new study to determine the distance to the Milky Way’s spiral arms. This image combines X-ray data from Chandra (blue) and optical data from Pan-STARRS (red, green and blue) showing X-ray rings generated by the GRB. The GRB is located at the center of the circles defining the rings, to the left of the X-ray data outlined by the white square.

X-ray & Optical Image Showing Rings from Dust Clouds.Credit: X-ray: NASA/CXC/INAF/B. Vaia et al.; Optical: Pan-STARRS; Image processing: NASA/CXC/SAO: N. Wolk, P. Edmonds


The researchers used three different GRBs to determine the distances to three spiral arms in the Milky Way. In order of increasing distances from the Galactic Center, they are the Perseus, the Outer, and the Outer Scutum-Centaurus arms. Along the direction to one of the GRBs they found that both the Outer and Outer Scutum-Centaurus arms are about 10% more distant than astronomers previously thought. The differences in the positions of these spiral arms based on the new study are depicted in another artist’s illustration where the updated positions of outermost spiral arms are shown in red and bordered by dashed lines.

Although this technique is a major improvement, it may be difficult to use it for further measurements because bright GRBs that are visible through the plane of the galaxy are rare.

A paper describing these results, led by Beatrice Vaia of Scuola Universitaria Superiore IUSS Pavia and University of Trento in Italy, has been recently published by the Astronomy & Astrophysics journal and is available here. NASA's Marshall Space Flight Center manages the Chandra program. The Smithsonian Astrophysical Observatory's Chandra X-ray Center controls science operations from Cambridge, Massachusetts, and flight operations from Burlington, Massachusetts.





Fast Facts for Milky Way Spiral Arms:

Credit: X-ray: NASA/CXC/INAF/B. Vaia et al.; Optical: Pan-STARRS; Image processing: NASA/CXC/SAO/N.Wolk & P.Edmonds; Illustration: NASA/CXC/SAO/M.Weiss
Release Date: July 1, 2026
Scale: Image is about 22 arcmin (400 light-years) across.
Category: Milky Way Galaxy
Coordinates (J2000): RA 19h 12m 24s | Dec +19° 43´ 46"
Constellation:
Sagitta
Observation Dates: October 22, 2022
Observation Time: 6 hours 2
Obs. ID: 27517
Instrument:
ACIS
References: B. Vaia et al. 2026, A&A, in press
Color Code: X-ray: blue; Optical: red, green, and blue
Distance Estimate: About 62,000 light-years from Earth



Sunday, July 05, 2026

Stellar motions can tighten constraints on dark matter's nature

Formation of a stellar stream, shown in the orbital plane (distances are given in kiloparsecs from the Galactic centre). As the progenitor — a star cluster or dwarf galaxy (blue) — orbits the Milky Way, stars are gradually stripped away by our galaxy's gravity and spread out along the orbit, building up the two thin arms of the stream over time. © MPA

The GD-1 stellar stream as seen by current surveys. Its track is not perfectly smooth; it shows gaps and a 'spur' of stars that a featureless dark matter halo cannot easily explain. This hints at perturbations from unseen clumps of matter. Background image: Fig. 1 from Ana Bonaca et al 2019 ApJ 880 38; image processing by MPA.

A snapshot from the simulation. The colours and arrows show the small velocity changes imparted to the stream stars by the surrounding dark matter clumps. Rather than modelling each clump individually, the simulation captures their collective statistical effect. © MPA



Although dark matter makes up most of the matter in the universe, what it is made of remains one of the biggest open questions in physics. One indirect clue to its particle nature is how clumpy it is on small scales, such as in dwarf galaxies and smaller. The smallest of these clumps are associated with few or no stars and cannot be seen directly; however, their gravity can perturb stellar streams, thin trails of stars that act as sensitive probes. MPA scientists have now demonstrated that analysing both the location and the movement of stellar stream's stars can pinpoint the scale at which dark matter stops clumping several times more precisely, achieving a level of sensitivity comparable to the most advanced methods currently available.

At the largest scales, a simple model of dark matter works well: a cold, slow-moving substance whose gravity pulls ordinary matter together to form galaxies. While this leading model accounts for much of what telescopes and observatories observe, it remains silent on a fundamental question: what is dark matter? There are many competing answers, ranging from massive elementary particles to small black holes and ultra-light wave-like particles, all of which reproduce the same large-scale universe. The models diverge on small scales: some predict that dark matter continues to gather into ever-smaller clumps, while others predict a cutoff, a minimum size below which clumps simply fail to form. Finding where this cutoff lies would provide a crucial clue to the identity of dark matter.

The problem is that the smallest clumps cannot gather enough ordinary matter to form stars, so they are essentially invisible to us. Their only trace is gravitational. The Milky Way offers a natural detector here. Over cosmic time, it has grown by absorbing many smaller star clusters and dwarf galaxies. As one of these is gradually pulled apart by our galaxy's gravity, its stars spread out along its orbit to form a long, narrow stream. As the stars move along the same orbit, the stream remains dynamically cold. This makes it highly sensitive to small disturbances: when a clump of dark matter passes nearby, its gravity shifts the stars slightly, leaving an imprint. The GD-1 stream is one of the most striking examples, displaying small features and gaps that cannot easily be explained by a smooth dark matter halo.

Most early studies modelled these clumps individually, interpreting a feature such as a gap as the mark of a single passing object. However, if low-mass clumps are as abundant as the leading model predicts, a stream is continuously perturbed by a whole population of them, with their effects overlapping. Consequently, the focus shifted to describing the clumps collectively. However, many population-level methods still resolve each encounter and sum them up, which becomes prohibitively expensive at low masses, where encounters are most numerous and competing dark matter models differ most.

The new study by MPA researchers Noemi Anau Montel and Fabian Schmidt avoids resolving encounters at all. It represents the entire population as a statistical pattern of density fluctuations at each scale. This field imparted many small velocity changes to the stars, which built up gradually rather than arriving as one sharp deflection. The cost no longer increases with the number of clumps, and any dark matter model can be tested by substituting a different pattern. Additionally, the model quantifies how sensitively the stream's appearance responds to a small change in any dark matter property. This enables the new framework to predict with forecasts, before the data is available, how accurately a future observation could measure each property.

The main advance comes from the motions of the stars. Earlier analyses relied mainly on the density of the stream, i.e. how the stars are spaced along its length. However, the same perturbations are also known to leave a pattern in the stars' velocities, affecting both their motion across the sky and their motion towards or away from us. The new study incorporates kinematic information into the forecast and demonstrates that using the motions of the stars, as well as their positions, improves the measurement of the cutoff scale by a factor of three to five. Specifically, the spacing of the stars alone locates the cutoff to within a factor of about ten, whereas adding the motions narrows it to a factor of roughly two. Even better, the constraints improve for an older stream that has been perturbed for a longer period of time.

These numbers are forecasts, not measurements. Nevertheless, the implication is significant: a single, accurately measured stream could constrain dark matter's behaviour on small scales as well as today's leading methods, such as the gravitational lensing of distant quasars and the counting of small satellite galaxies in the Milky Way (see also this press release from 2025). Because a stream is a purely local, purely gravitational probe, its sources of error are independent of these methods, offering a valuable cross-check.

The required data are now becoming available from the precise positions of the Gaia satellite, the velocity measurements of the DESI survey, and dedicated instruments such as the VIA Project. However, two challenges remain: separating the perturbations caused by visible structures, such as gas clouds and the galactic bar, from those caused by dark matter; and handling the rare close passes of the largest clumps, which lie outside the weak accumulating regime discussed here.

Source: Max Planck Institute for Astrophysics/Research Highlights


Authors:

Dr. Noemi Anau Montel
Tel: 2215
noemiam@mpa-garching.mpg.de

Dr. Fabian Schmidt
Scientific Staff
Member of the works council, Representative of the Scientific Coworkers
Tel:
2274
fschmidt@mpa-garching.mpg.de



Original publication:

Noemi Anau Montel, Fabian Schmidt
A differentiable forward model for weakly perturbed stellar streams: substructure forecasts from density and kinematics spectra
submitted


Source