Saturday, April 18, 2026

Tracing the Origins of Mysterious Gas Clouds near the Galactic Center

The picture shows the dynamic environment around the supermassive black hole at the Milky Way's center, featuring the newly discovered gas cloud G2t alongside previously known clouds G1 and G2, whose similar orbits suggest a common origin from the star system IRS16SW. © ESO/D. Ribeiro for the MPE GC team

The integration team after successfully mounting ERIS to the Cassegrain focus of UT4 at the VLT. Adhering to the restrictions associated with pandemic, both for travel and while at the observatory, make the whole process of integration and testing much more arduous than in normal times. © MPE/ESO/ERIS


New observations and simulations by a team of researchers led by MPE reveal that a massive binary star near our Galaxy’s center is responsible for creating a series enigmatic gas clouds — compact gas clumps that help feed the supermassive black hole Sagittarius A*.

The center of our Milky Way is a remarkably dense and dynamic region. At its heart lies the supermassive black hole Sagittarius A* (Sgr A*), surrounded by stars, gas, and dust moving under extreme gravitational forces. These surroundings provide a natural laboratory for studying how matter behaves close to a black hole and how such objects are supplied with new material.

Over the last twenty years, astronomers have discovered several compact gas clouds near Sgr A* using infrared observations. These “clumps” are important clues to understanding how gas may eventually reach the black hole. Yet their exact origin and the physical processes that shape them have remained uncertain.

The G‑Clouds: A Growing Family

In 2012, astronomers identified a first, compact, ionized gas cloud named G2. It has a mass of a few Earths and emits light from hydrogen and helium, typical for hot, dusty gas. G2 follows an elongated orbit around Sgr A* and shows a faint trailing structure, G2t. Revisiting earlier observations revealed shortly after a similar object, G1, moving along a comparable orbit.

G1, G2, and G2t were proposed to be denser clumps within a common stream of gas. Moderate density fluctuations can lead to a clumpy appearance because a cloud’s brightness increases with the square of its density. Recently, researchers found that gas from G2’s tail has condensed into a third compact clump moving along a similar path, which one now could call G3, except that this name had by now already been given to a different object. Together, these objects form a coherent structure — the G1–2–3 streamer— tracing material that flows through the Galactic Center.

Calculations show that the infall of one such clump, roughly one Earth mass every decade, could provide enough material to sustain Sgr A*’s current activity. Understanding how these clumps form is therefore key to explaining how the black hole is fuelled.

Searching for the Source

Several origins have been proposed: stellar winds from massive stars, explosive events such as novae, or tidal stripping by Sgr A*. To test these ideas, an international team led by MPE used adaptive-optics-assisted spectrographs SINFONI and ERIS, which enable sharp infrared spectroscopy. Focusing on the hydrogen Brackett‑γ emission line, they reconstructed the orbits of the three clouds from their positions and velocities.

The analysis revealed that G1, G2, and G2t travel on orbits with almost identical orientation and shape. The chance that three unrelated objects share such specific orbital parameters is vanishingly small. This indicates a common origin for all three clumps.

A Binary Star as the Creator

By tracing the motions of the gas streamer backward in space and radial velocity, the researchers identified a viable source: the massive contact binary star IRS 16SW, located in the clockwise disk of young stars orbiting Sgr A*. The small differences between the G‑cloud orbits can be explained by the binary’s own orbital motion.

Hydrodynamical simulations further support this conclusion. They show that gas clumps can form where the stellar winds from the binary collide with the surrounding medium, producing a shock between the two stars. There, gas accumulates and becomes compressed, eventually detaching as individual clumps that travel inward — like what is observed in the G1–2–3 streamer.

What does it mean?

These findings suggest that stellar winds from massive stars in the Galactic Center can continually supply material to the black hole. The result connects stellar evolution, gas dynamics, and black‑hole feeding into one consistent picture — showing how star formation and black‑hole growth may be linked even in our own Galaxy.



Contacts:

Dr. Stefan Gillessen
Scientist Infrared-Group
Tel.: +49 89 30000-3839
Email: Stefan.gillessen@mpe.mpg.de
Max-Planck-Institut für extraterrestrische Physik, Garching

Prof. Dr. Frank Eisenhauer
Direktor der Infrarot-Gruppe am MPE
Tel.: +49 89 30000-3100
Fax.: +49 89 30000-3102
Email: eisenhau@mpe.mpg.de
Max-Planck-Institut für extraterrestrische Physik, Garching

Prof. Dr. Reinhard Genzel
Direktor der Infrarot-Gruppe am MPE
Tel.: +49 89 30000-3280
Fax.: +49 89 30000-3601
Email: genzel@mpe.mpg.de
Max-Planck-Institut für extraterrestrische Physik, Garching



Original Publication

 S. Gillessen, F. Eisenhauer, J. Cuadra, R. Genzel, et al.
The gas streamer G1–2–3 in the Galactic center
A&A, 707 (2026) A79

Source | DOI


Further Information

Series: Paper of the Month

The series “Paper of the month” features a scientific highlight of MPE researchers.


 

Sharper infrared eyes for the VLT: ERIS sees first light

November 23, 2022

The Enhanced Resolution Imager and Spectrograph (ERIS), a science instrument which was built by a consortium under the leadership of the Max Planck Institute for Extraterrestrial Physics, has successfully completed its first test observations. One of them exposed the heart of the galaxy NGC 1097 in mesmerising detail.





A look deep into the early universe: First infrared interferometry of a quasar at redshift 4

September 17, 2025

New GRAVITY+ and ERIS observations uncover surprising black hole properties and powerful gas outflows in the early cosmos. 

 

 


Hyper-luminous, Yet Surprisingly Organized

July 15, 2024

Members of the Infrared Group at the Max Planck Institute for Extraterrestrial Physics (MPE), including Daizhong Liu and Natascha M. Förster Schreiber, and other international institutes, showed that a Hyper-luminous Infrared Galaxy (HyLIRG) can also arise in a massive turbulent rotating disk within a single galaxy, where the gas is organized in a structured way, rather than by collisions of several galaxies. 
 
 
 
 


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Friday, April 17, 2026

NASA’s Webb Redefines Dividing Line Between Planets, Stars

Astronomers used NASA’s James Webb Space Telescope to directly image 29 Cygni b, which weighs 15 times Jupiter. They found evidence for heavy chemical elements like carbon and oxygen, which strongly suggests it formed like a planet by accretion within a protoplanetary disk. Credit Image: NASA, ESA, CSA, William Balmer (JHU, STScI), Laurent Pueyo (STScI); Image Processing: Alyssa Pagan (STScI)
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Exoplanet 29 Cygni b, seen in this artist’s concept, is a gas giant weighing about 15 times the mass of Jupiter. Astronomers studied 29 Cygni b with NASA’s James Webb Space Telescope. They determined that it likely formed from accretion rather than disk fragmentation. Credit Illustration: NASA, ESA, CSA, Joseph Olmsted (STScI)


Planets, like those in our solar system, form in a bottom-up process where small bits of rock and ice clump together and grow larger over time. But the heftier the planet, the harder it is to explain its formation that way.

Astronomers used NASA’s James Webb Space Telescope to examine 29 Cygni b, an object about 15 times as massive as Jupiter orbiting a nearby star. They found multiple lines of evidence that 29 Cygni b indeed formed from this bottom-up process, bringing new insights into how the heftiest planets come to be. A paper describing these findings published Tuesday in The Astrophysical Journal Letters.

The planet formation process is broadly understood to occur within gigantic disks of gas and dust around stars through a process called accretion. Dust gloms together into pebbles, which collide and grow larger and larger, forming protoplanets and eventually planets. The largest then collect gas to become giants like Jupiter. Since it takes more time for gas giants to form, and the disk of planet-forming material eventually evaporates and disappears, planetary systems end up with many more small planets than large planets.

In contrast, stars form when a vast cloud of gas fragments and each piece collapses under its own gravity, growing smaller and denser. A similar fragmentation process could theoretically occur within protoplanetary disks as well. That could explain why some very massive objects are found billions of miles from their host stars, in regions where the protoplanetary disk should have been too tenuous for accretion to occur.

29 Cygni b sits on the dividing line between what can be explained by these two different mechanisms. It weighs 15 times Jupiter and orbits its star at an average distance of 1.5 billion miles (2.4 billion kilometers), about the same as Uranus in our solar system. The research team targeted it because it could potentially result from either process.

“In computer models, it’s very easy for fragmentation in a disk to run away to much higher masses than 29 Cygni b. This is the lowest mass you could plausibly get. But at the same time, it’s about the highest mass you could get from accretion,” said lead author William Balmer of the Johns Hopkins University and the Space Telescope Science Institute, both in Baltimore.

Balmer’s observing program used Webb’s NIRCam (Near-Infrared Camera) in its coronagraphic mode to directly image 29 Cygni b. This planet was the first of four objects targeted by the program, all of which are known to weigh between 1 and 15 times as much as Jupiter. The team also required their targets to orbit within about 9 billion miles (15 billion kilometers) of their stars.

The planets were all young and still hot from their formation, ranging in temperature from about 1,000 to 1,900 degrees Fahrenheit (530 to 1,000 degrees Celsius). This would ensure their atmospheric chemistry was similar to the planets of HR 8799, whose system Balmer studied previously.

By choosing appropriate filters, the team was able to look for signs of light being absorbed by carbon dioxide (CO2) and carbon monoxide (CO), which allowed them to determine the amount of those heavier chemical elements, which astronomers collectively call metals.

They found strong evidence that 29 Cygni b is enriched in metals relative to its host star, which is similar to our Sun in its composition. Given the planet’s mass, the amount of heavy elements it contains is equivalent to about 150 Earths. This suggests that it accreted large amounts of metal-enriched solids from a protoplanetary disk.

The team also used a ground-based optical telescope array called CHARA (Center for High Angular Resolution Astronomy) to determine if the planet’s orbit is aligned with the spin of the star. They confirmed that alignment, which would be expected for an object that formed from a protoplanetary disk.

“We were able to update the planet’s orbit, and also observed the host star to determine its orientation with respect to that orbit,” said Ash Messier, co-author and a graduate student at Johns Hopkins University. “We showed that the inclination of the planet is well-aligned with the spin axis of the star, which is similar to what we see for the planets of our solar system.”

“Put together, this evidence strongly suggests that 29 Cygni b formed within a protoplanetary disk through rapid accretion of metal-rich material, rather than through gas fragmentation,” said Balmer. “In other words, it formed like a planet and not like a star.”

As the team gathers data on the other three targets within their program, they plan to look for evidence of compositional differences between the lower-mass and higher-mass planets. This should provide additional insights into their formation mechanisms.

The James Webb Space Telescope is the world’s premier space science observatory. Webb is solving mysteries in our solar system, looking beyond to distant worlds around other stars, and probing the mysterious structures and origins of our universe and our place in it. Webb is an international program led by NASA with its partners, ESA (European Space Agency) and CSA (Canadian Space Agency).



Details:

Last Updated: Apr 14, 2026
Location: NASA Goddard Space Flight Center

Contact Media:

Laura Betz
NASA’s Goddard Space Flight Center
Greenbelt, Maryland
laura.e.betz@nasa.gov

Christine Pulliam
Space Telescope Science Institute
Baltimore, Maryland

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Thursday, April 16, 2026

Most Close Pairs of Stars Are Born as Cosmic Twins

An artist's rendition of pair of twin stars being born in the HOPS-312 system in Orion.
Credit: NSF/AUI/NSF NRAO/B. Saxton. Hi-Res File


New research from ALMA suggests disk fragmentation may form close-companion protostellar systems

A new study of infant stars in the Perseus and Orion star-forming regions suggests that most close pairs of stars are born as twins in the same disk, rather than drifting together later from larger distances. By watching powerful streams of gas blasting away from baby stars, a team of researchers has shown that most close pairs of stars likely form side‑by‑side in the same spinning disk of gas and dust.

Many stars in our galaxy don’t live alone like the Sun. Roughly half of Sun-like stars are part of a pair or even a small family of stars that orbit each other. Young stars are even more likely to have companions, which tells astronomers that forming in multiples is a normal part of how stars are born.

What hasn’t been clear is how close pairs of stars—separated by only a few times the width of our solar system—actually come together. Do they form together in the same disk of gas and dust, or do they start far apart and slowly move closer over time?

This new research, led by undergraduate student Ryan Sponzilli of the University of Illinois Urbana-Champaign, tests two leading ideas for how close-companion protostars form:

1. A single, massive disk of gas and dust around a newborn star becomes unstable and breaks into two or more clumps, each collapsing to form a star. This disk fragmentation tends to produce close pairs in an organized, aligned configuration.

2. Turbulence in a larger cloud core causes it to break into widely separated clumps that form stars far apart, which are later pulled inward through complex gravitational interactions. This process of turbulent fragmentation and migration should leave stellar spins and orbits in more random orientations.

“Figuring out which process is more common in the formation of these ‘twins’ will help us understand more about not only stars, but also what kinds of planetary systems might form around them,” shares Sponzilli.

To test these ideas, the research team studied 51 very young protostellar star systems that host close companion stars in the Perseus and Orion molecular clouds, some of the nearest stellar nurseries to Earth. ALMA observations mapped both the dust surrounding the stars and jets of molecular gas blasting away from them.

In 38 of the systems, fast, narrow streams of outflowing gas were clearly observed. These outflows show which way the system is spinning. The outflows usually shoot out at right angles to the disk of material around each star, so their direction is a good guide to how the system is oriented in space.

The researchers compared the direction of each outflow to the line connecting the two stars in a pair. This let them work out whether the system looked organized, as expected if the stars formed together in a disk, or more random, as expected if they formed separately and later moved closer.

The team also built simple computer models of what they should see in the sky for each of the two formation scenarios. When they compared these models to their 42 outflow measurements, the real data matched best with a picture where the outflows tend to line up at right angles to the line between the stars, which is expected if the stars formed together in a single disk.

“The results point to disk fragmentation as the main way that close pairs of baby stars form, at least in the young regions studied here,” adds co-author Leslie Looney, Sponzilli’s professor at the University of Illinois Urbana-Champaign.

By showing that many close stellar twins are likely born together in a single spinning disk, this study strengthens the link between the earliest stages of star formation and the later evolution of planetary systems around multiple stars. Understanding these early alignments will help astronomers predict how common aligned planetary orbits might be in binary systems and how stable those planetary systems can become over time.



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

 About ALMA
The Atacama Large Millimeter/submillimeter Array (ALMA), an international astronomy facility, is a partnership of the European Southern Observatory (ESO), the U.S. National Science Foundation (NSF) and the National Institutes of Natural Sciences (NINS) of Japan in cooperation with the Republic of Chile. ALMA is funded by ESO on behalf of its Member States, by NSF in cooperation with the National Research Council of Canada (NRC) and the National Science and Technology Council (NSTC) in Taiwan and by NINS in cooperation with the Academia Sinica (AS) in Taiwan and the Korea Astronomy and Space Science Institute (KASI).

ALMA construction and operations are led by ESO on behalf of its Member States; by the National Radio Astronomy Observatory (NRAO), managed by Associated Universities, Inc. (AUI), on behalf of North America; and by the National Astronomical Observatory of Japan (NAOJ) on behalf of East Asia. The Joint ALMA Observatory (JAO) provides the unified leadership and management of the construction, commissioning and operation of ALMA.

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Wednesday, April 15, 2026

See and hear galaxies evolve from the dawn of the universe

The panel on the left shows the so-called cosmic web, where the colour encodes the projected density of gas and stars. The two panels on the right zoom into two of the many galaxies formed in the simulations. These images show the stellar light obscured by dust for a disc galaxy seen face-on (top right) and another disc galaxy seen edge-on (bottom right). Credit: Schaye et al. (2026)
Licence type: Attribution (CC BY 4.0)

The most realistic picture yet of how galaxies formed and then evolved from the beginning of time has been revealed in a suite of new and unique audiovisual simulations.)

This data, published today in Monthly Notices of the Royal Astronomical Society, shows that the standard cosmological model can successfully explain the observed growth of galaxies, from the first billion years after the Big Bang to the present day, when key physics is included.

Unlike earlier simulations, the COLIBRE 'virtual universes' model the cold gas and cosmic dust inside galaxies – the raw materials from which stars form and which strongly affect how galaxies look in telescopes.

By including these previously missing ingredients and using far more computing power than ever before, the simulations successfully reproduce real galaxies, both in the present-day universe and in the early universe as seen by the James Webb Space Telescope (JWST).

"Much of the gas inside real galaxies is cold and dusty, but most previous large simulations had to ignore this," said project leader Professor Joop Schaye, of Leiden University. "With COLIBRE, we finally bring these essential components into the picture."


The results show that our standard model of the universe can explain galaxy formation more accurately than previously thought, while also opening up powerful new ways to compare theory with observations and to explore a virtual universe through visuals, sound, and interactive tools.

Digital cold gas and dust grains

According to the international team of researchers, their COLIBRE simulations break new ground in several ways. Earlier simulations artificially prevented gas inside galaxies from cooling below about 10,000 degrees Fahrenheit – hotter than the surface of the Sun – because modelling colder gas was too complex. Yet, observations show that stars form in cold gas. COLIBRE includes the additional physical and chemical processes needed to model this cold interstellar gas directly.

COLIBRE also simulates small dust grains, which can greatly influence galactic gas. These solid particles can help hydrogen molecules to form, which dominate the cold gas content of galaxies. The dust also shields gas from harsh ultraviolet radiation and strongly affects how galaxies appear in telescopes. Dust absorbs ultraviolet and optical light from stars and re-emits it in the infrared, shaping many astronomical observations. By modelling dust directly, COLIBRE opens new ways to compare simulations with real data.

Thanks to advances in algorithms and supercomputing, COLIBRE uses up to 20 times more resolution elements than earlier simulations, allowing larger volumes to be simulated in greater detail and with better statistics.

A new laboratory

COLIBRE demonstrates that realistic treatments of cold gas, dust, and outflows driven by stars and black holes are crucial for understanding galaxy evolution, the researchers say. It provides a powerful new laboratory for testing theories, interpreting observations, and creating "virtual observations" to check how astronomers analyse real data.

The findings also show that the standard cosmological model remains consistent with observations of galaxy evolution, including some that were thought to be challenging, such as the masses of galaxies in the early universe.

"Some early JWST results were thought to challenge the standard cosmological model," said Dr Evgenii Chaikin, of Leiden University, lead author of several accompanying COLIBRE papers and co-author of the main study.

"COLIBRE shows that, once key physical processes are represented more realistically, the model is consistent with what we see."

Still, not everything has been explained yet. The enigmatic 'Little Red Dots' discovered by JWST, possibly the seeds of supermassive black holes, are not predicted by COLIBRE, which assumes such seeds already exist. Modelling their formation will require even higher resolution simulations and new physics, pointing the way for future work.

The simulations were run using the SWIFT simulation code on the COSMA8 supercomputer at the Institute for Computational Cosmology at Durham University, which is hosted on behalf of the DiRAC national facility in the UK. The largest simulation required 72 million CPU hours, and the full model took nearly 10 years to develop by an international team spanning Europe, Australia, and the United States.

Carlos Frenk, Ogden Professor of Fundamental Physics at the Institute for Computational at Durham University, and a core member of the COLIBRE team said: "It is exhilarating to see 'galaxies' come out of our computer that look indistinguishable from the real thing and share many of the properties that astronomers measure in real data such as their number, luminosities, colours and sizes.

"I like to tease my observer colleagues by asking 'which galaxy catalogue do you think these images came from?'"
He added: “What is most remarkable is that we are able to produce this synthetic universe purely by solving the relevant equations of physics in the expanding universe.”

The scientists point out that it will take years to analyse the data that has already been produced. Most simulations were completed in 2025, although some of the simulations with the highest resolution are still running and are expected to finish after the summer.

A universe you can see and hear

Beyond traditional data products, the team has developed new ways to explore the simulations. This includes "sonified videos", where sound encodes additional physical information, as well as interactive maps that allow users to explore the virtual universes.

"We're excited not just about the science, but also about creating new ways to explore it," said Dr James Trayford, of the University of Portsmouth, who led the development of COLIBRE's dust model and the sonification of its visualisations.

"These tools could provide new insights, make our field more accessible, and help us build intuition for how galaxies grow and evolve."



Media contacts:

Sam Tonkin
Royal Astronomical Society
Mob: +44 (0)7802 877 700
press@ras.ac.uk

Science contacts:

Joop Schaye
Leiden Observatory, Leiden University
schaye@strw.leidenuniv.nl

Evgenii Chaikin
Leiden Observatory, Leiden University
chaikin@strw.leidenuniv.nl

James Trayford
Institute of Cosmology and Gravitation, University of Portsmouth
james.trayford@port.ac.uk

Professor Carlos Frenk
Durham University
c.s.frenk@durham.ac.uk


Images & video

Images, videos, and interactive material from the COLIBRE simulations are available at:

https://colibre-simulations.org

Media, developed using COLIBRE, can be found here: sonified videos, interactive sliders, and interactive maps.


Further information
The paper ‘The COLIBRE project: cosmological hydrodynamical simulations of galaxy formation and evolution’ by Schaye et al. has been published in Monthly Notices of the Royal Astronomical Society. DOI: 10.1093/mnras/stag375.

The paper ‘COLIBRE: calibrating subgrid feedback in cosmological simulations that include a cold gas phase’ by Chaikin et al. has been published in Monthly Notices of the Royal Astronomical Society. DOI: 10.1093/mnras/stag300.


Notes for editors

 About the COLIBRE collaboration
The COLIBRE collaboration is an international team led by Professor Joop Schaye, of Leiden University. It includes researchers from the UK (Durham University, Portsmouth, Hull, Liverpool John Moores, Nottingham), Austria (University of Vienna), Italy (University of Milano-Biococca), Australia (University of Western Australia), Belgium (University of Ghent) and the US (University of Pennsylvania).

A team of several Durham physicists at the Institute for Computational Cosmology contributed to the design and execution of the simulations and to the scientific analysis of the data. Members of this team wrote key elements of the software used for the simulations and helped run them on the "COSMA" supercomputer at Durham. Members of the team are leading major sub-projects analysing the simulation results and comparing them to observed data.

 About NOVA
The Netherlands Research School for Astronomy (NOVA, www.astronomie.nl) is the alliance of the astronomical institutes of the universities of Amsterdam, Groningen, Leiden, and Nijmegen. The mission of Top Research School NOVA is to carry out frontline astronomical research in the Netherlands, to train young astronomers at the highest international level, and to share its new discoveries with society. The NOVA laboratories are specialised in building state-of-the-art optical/infrared and submillimeter instrumentation for the largest telescopes on earth.

 About the Royal Astronomical Society
The Royal Astronomical Society (RAS), founded in 1820, encourages and promotes the study of astronomy, solar-system science, geophysics and closely related branches of science.

The RAS organises scientific meetings, publishes international research and review journals, recognises outstanding achievements by the award of medals and prizes, maintains an extensive library, supports education through grants and outreach activities and represents UK astronomy nationally and internationally. Its more than 4,000 members (Fellows), a third based overseas, include scientific researchers in universities, observatories and laboratories as well as historians of astronomy and others.

The RAS accepts papers for its journals based on the principle of peer review, in which fellow experts on the editorial boards accept the paper as worth considering. The Society issues press releases based on a similar principle, but the organisations and scientists concerned have overall responsibility for their content.


Keep up with the RAS on Instagram, Bluesky, LinkedIn, Facebook and YouTube.

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Submitted by Sam Tonkin on Mon, 13/04/2026 - 13:00

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Tuesday, April 14, 2026

The Local Universe’s Expansion Rate Is Clearer Than Ever, but Still Doesn’t Add Up

PR Image noirlab2611a
Artist’s interpretation of the cosmic distance ladder

PR Image noirlab2611b
Graphic representation of the Hubble tension


A new synthesis of astronomical measurements confirms a persistent mismatch that could point to physics beyond current models

An international collaboration of astronomers has produced one of the most precise measurements yet of how fast the local Universe is expanding. The result deepens one of the most significant challenges in modern cosmology. John Blakeslee, astronomer at NSF NOIRLab, funded by the U.S. National Science Foundation, is a member of the collaboration, and telescopes across two NSF NOIRLab Programs contributed data.

Astronomers have sought to measure the expansion rate of the Universe using two fundamentally different approaches. One method relies on measuring distances to stars and galaxies in the nearby Universe. The other uses measurements of the cosmic microwave background to predict what the expansion rate would be today under the standard model of cosmology.

These two approaches are expected to yield the same result, but they don’t. Measurements based on the nearby Universe consistently indicate a higher expansion rate — around 73 kilometers per second per megaparsec — while predictionderived from the early Universe yield a lower value, closer to 67 or 68. Although the numerical difference is modest, it is s far larger than can be explained by statistical uncertainty. This persistent disagreement, known as the Hubble tension, has now been observed across multiple independent studies and techniques.

By bringing together decades of independent observations into a single, unified framework, an international collaboration of astronomers has achieved the most precise direct measurement to date of the expansion rate of the nearby Universe. In a paper published on 10 April in Astronomy & Astrophysics, the H0 Distance Network (H0DN) Collaboration reports a value of the Hubble constant of 73.50 ± 0.81 kilometers per second per megaparsec, corresponding to a precision of just over 1%.

The study, “The Local Distance Network: a community consensus report on the measurement of the Hubble constant at ∼1% precision,” is the outcome of a broad community effort launched at the International Space Science Institute (ISSI) Breakthrough Workshop, “What’s under the H0od?”, held at ISSI in Bern, Switzerland, in March 2025.

“This isn’t just a new value of the Hubble constant,” the collaboration notes, “it’s a community-built framework that brings decades of independent distance measurements together, transparently and accessibly.”

NSF NOIRLab contributed both expertise and observational data to this effort. John Blakeslee, astronomer and Director of Research and Science Services at NSF NOIRLab, is a member of the collaboration. The study includes data from telescopes at NSF Cerro Tololo Inter-American Observatory (CTIO) in Chile and NSF Kitt Peak National Observatory (KPNO) in Arizona, both Programs of NSF NOIRLab. Those data were incorporated into a broader, collaborative framework spanning both ground and space-based observatories, helping to strengthen the overall result.

Rather than relying on a single method, the team constructed a “distance network” that links many overlapping techniques for measuring distances across the local Universe. These include observations of pulsating Cepheid variable stars, red giant stars that shine with a known brightness, Type Ia supernovae, and certain types of galaxies. This approach enables multiple independent paths to the same final result, and allows for a critical test: is the discrepancy caused by an error within a single method? The results indicate that this is unlikely. Even when individual techniques are removed from the analysis, the overall result changes only minimally. Independent measurements remain consistent with one another, reinforcing the robustness of the locally measured expansion rate.

“This work effectively rules out explanations of the Hubble tension that rely on a single overlooked error in local distance measurements,” the authors conclude. “If the tension is real, as the growing body of evidence suggests, it may point to new physics beyond the standard cosmological model.”

The implications are significant. The lower expansion rate inferred from the early Universe depends on the standard model of cosmology, which describes how the Universe has evolved since the Big Bang. If that model is incomplete — for example, if it does not fully account for the behavior of dark energy, new particles, or modifications to gravity — its predictions for the present-day expansion rate would be affected.

In that case, the Hubble tension may not be the result of measurement error, but rather evidence that the current model of the Universe is missing a key component. The local distance network also establishes a framework for future investigations. By making its methods and data openly available, the collaboration has created a foundation that can be expanded with new observations. With next-generation observatories expected to provide even more precise measurements, astronomers aim to determine whether this discrepancy will ultimately be resolved or continue to point toward new physics.



More information

This research is presented in a paper titled “The Local Distance Network: A community consensus report on the measurement of the Hubble constant at ∼1% precision” to appear in Astronomy & Astrophysics. DOI: 10.1051/0004-6361/202557993

The results are presented by the H0DN Collaboration.

NSF NOIRLab, the U.S. National Science Foundation center for ground-based optical-infrared astronomy, operates the International Gemini Observatory (a facility of NSF, NRC–Canada, ANID–Chile, MCTIC–Brazil, MINCyT–Argentina, and KASI–Republic of Korea), NSF Kitt Peak National Observatory (KPNO), NSF Cerro Tololo Inter-American Observatory (CTIO), the Community Science and Data Center (CSDC), and NSF–DOE Vera C. Rubin Observatory (in cooperation with DOE’s SLAC National Accelerator Laboratory). It is managed by the Association of Universities for Research in Astronomy (AURA) under a cooperative agreement with NSF and is headquartered in Tucson, Arizona.

The scientific community is honored to have the opportunity to conduct astronomical research on I’oligam Du’ag (Kitt Peak) in Arizona, on Maunakea in Hawai‘i, and on Cerro Tololo and Cerro Pachón in Chile. We recognize and acknowledge the very significant cultural role and reverence of I’oligam Du’ag to the Tohono O’odham Nation, and Maunakea to the Kanaka Maoli (Native Hawaiians) community.

The International Space Science Institute (ISSI) is an Institute of Advanced Studies, where scientists from all over the world meet in a neutral, welcoming, and multi-disciplinary setting to discuss and publish about relevant and compelling topics related to four Disciplines: Astrophysics, Heliophysics, Planetary Science and Earth Science. ISSI’s mission is to advance science by facilitating scientific community interactions, meetings, discussions, and publications aimed at a deeper understanding of results from different space missions, ground-based observations, and theory. This is achieved through a broad portfolio of scientific opportunities that include: International Teams, Workshops, Working Groups, Fora, or visits of individual Visiting Scientists. For additional information related to ISSI and to the opportunities it offers, see: www.issibern.ch.


Links

Contacts:

Josie Fenske
Public Information Officer
NSF NOIRLab
Email: josie.fenske@noirlab.edu

Fabio Crameri
Communication Scientist
ISSI
Email: fabio.crameri@issibern.ch

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Monday, April 13, 2026

Black hole X-ray binary becomes bright (again)

Artistic impression of a stellar mass black hole accreting from a binary companion and the winds emitted from the accretion disk. Credit: Gabriel Pérez Díaz, SMM (IAC). Download Image

During the past week, NuSTAR performed an observation coordinated with the JAXA/NASA/ESA XRISM observatory of the accreting stellar-mass black hole (BH) AT2019wey. AT2019wey is a low-mass X-ray binary (LMXB) system harboring a rapidly spinning BH seen at a low inclination. AT2019wey was first discovered in 2019 as an optical outburst, followed by an X-ray brightening about six months later. Unlike most BH LMXBs which fade on a timescale of a few months to a year, the outburst of AT2019wey remained bright for several years, decaying around the end of 2025. However, around the beginning of 2026, the system started to rebrighten, approaching the similar flux levels as during the original outburst. Despite being observed numerous times by NuSTAR since its first discovery, this joint XRISM-NuSTAR campaign offers a unique probe of this unusual system. In particular the observing program aims to probe tentative claims of X-ray absorption in the Fe band (around 7 keV). Such features are believed to be caused by equatorial ionized outflows (winds) originating from the accretion disk in the system. The novelty of the program comes from the fact that such features are not expected to be observed in low-inclination systems, such as AT2019wey. This study will expand the understanding of the geometry of ionized outflows in X-ray binaries, and of their impact on accretion. Furthermore, by simultaneously leveraging the high-resolution capabilities of XRISM with the broad pass band and sensitivity of NuSTAR, this study will test the impact of the variability of coronal activity on disk winds, and it will enhance the ability to measure properties of the system such as the BH spin, the inclination of the system, elemental abundances, and the ionization and density of the atmosphere of the accretion disk.

Author: Dr. Paul Draghis, Kavli Postdoctoral Fellow at the MIT Kavli Institute for Astrophysics and Space Research.


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Sunday, April 12, 2026

How Jupiter Cultivated More Large Moons than Saturn — A magnetospheric cavity explains the difference

Artist’s impression of the simulations conducted in this research. Jupiter (lower left) has a strong magnetic field which creates a cavity in its circumplanetary disk. Saturn (upper right) lacks a strong magnetic field so its circumplanetary disk evolves without a cavity. Credit: Yuri I. Fujii/L-INSIGHT [Kyoto University], Shinichiro Kinoshita.  Image (5.0MB)

The Solar System’s two largest gas giant planets, Jupiter and Saturn, have extensive but very different families of moons orbiting them. New simulations conducted on the PC cluster at the Center for Computational Astrophysics (CfCA), National Astronomical Observatory of Japan (NAOJ) showed that the planet’s magnetic field plays a role in creating an environment where the new moons can survive and grow, thus shaping the evolution of the system.

Jupiter has more than 100 reported moons, including four large ones (Ganymede, Callisto, Io, and Europa). Saturn has more than 280 reported moons, but only one large one (Titan). So it is a puzzle why Saturn managed to cultivate more moons, but fewer large moons than Jupiter.

A team led by Kyoto University, including researchers from institutes in Japan and China, used the PC cluster at CfCA, NAOJ, to simulate the formation of the moon systems around Jupiter and Saturn. This simulation recreated the planets’ internal structure to calculate the thermal evolution of Jupiter and Saturn and how their magnetic fields have varied over time.

Moons form from material in a “circumplanetary disk” of gas and dust orbiting the young planet. The disk nurtures the young moons, but interactions with the disk may cause them to fall into the planet. The simulations showed that young Jupiter generated a strong planetary magnetic field that created a safe “cavity” around the planet where its young large moons were prevented from migrating too close to their host planet. Young Saturn lacked a strong magnetic field, so only one large moon managed to survive.

“Testing planet formation theory is somewhat difficult because we have only our Solar System for reference, but there are multiple satellite systems close to us whose detailed characteristics we can observe,” says Yuri I. Fujii, primary author of the report announcing these findings. Next, the team is interested in expanding their theory to other moons and potential exomoon systems.



Detailed Article(s)

How Jupiter Cultivated More Large Moons than Saturn —— A magnetospheric cavity explains the difference

Center for Computational Astrophysics

 Release Information

 Researcher(s) Involved in this Release
  • Yuri Fujii (Graduate School of Human and Environmental Studies, Kyoto University)
  • Masahiro Ogihara (Tsung-Dao Lee Institute, Shanghai Jiao Tong University)
  • Yasunori Hori (Okayama University)

Coordinated Release Organization(s)
  • Kyoto University
  • Okayama University
  • National Astronomical Observatory of Japan, NINS
  • Fujii et al. “Different architecture of Jupiter and Saturn satellite systems from magnetospheric cavity formation” in Nature Astronomy, DOI: 10.1038/s41550-026-02820-x

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Saturday, April 11, 2026

First Close Pair of Supermassive Black Holes Detected

The artistic rendering shows the center of the galaxy Markarian 501, from which two powerful jets emanate. The supermassive black hole at the centre, whose existence was already known, partially bends the light from the jet behind it into a so-called Einstein ring. This curved jet most likely originates from a second, unobserved black hole. The radio observations are visible as contours in the background. Emma Kun / HUN-REN Konkoly Observatory / Made with the support of AI

At the center of the galaxy Markarian 501, there appears to be not just one supermassive black hole, but two. Radio observations over several years suggest that the duo could merge in as short as 100 years.


To the point:
  • An international research team led by Silke Britzen from the Max Planck Institute for Radio Astronomy (MPIfR) has imaged two large particle streams (jets) in the core of a galaxy.

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  • It is the first image of its kind and provides direct evidence of a pair of supermassive black holes orbiting each other very closely.

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  • The pair is believed to be in the final phase before merging. Until now, it was unclear whether this phenomenon could exist and whether it could be observed.


Current findings suggest that there is a supermassive black hole at the centre of almost every large galaxy, with a mass millions or even billions of times greater than that of our Sun. It is still unclear exactly how they can reach such enormous masses. Collecting (accreting) gas from the surrounding area alone would take too long, so it is likely that they have to merge with other massive black holes. Galaxy collisions have been observed throughout our Universe. It is thus very likely that the supermassive black holes at the centres of these colliding galaxies also merge, first orbiting each other ever closer and ultimately coalescing into one.

Telltale particle beam

However, theoretical models cannot yet accurately describe this final phase. Complicating matters further, no close pair of massive black holes has yet been reliably detected, despite collisions between galaxies being commonplace on cosmic timescales. A recent study of the galaxy Markarian 501 (Mrk 501) in the constellation Hercules has changed that. An international team led by Silke Britzen from the Max Planck Institute for Radio Astronomy (MPIfR) in Bonn found direct evidence of such a pair at the heart of Mrk 501. Their work has been accepted for publication in the journal Monthly Notices of the Royal Astronomical Society, and will appear in an upcoming issue.

The black hole at the centre of Mrk 501 ejects a powerful jet of particles travelling at nearly the speed of light into space. For the study, the team analysed high-resolution observations of the region. These cover various radio frequencies and were collected on dozens of days over a period of approximately 23 years. This long-term data reveals not only a single jet, but a second one as well. It is the first direct image of such a system at the centre of a galaxy, and a clear indication of the existence of a second supermassive black hole. “We searched for it for so long, and then it came as a complete surprise that we could not only see a second jet, but even track its movement,” reports Silke Britzen.

Close dance of black holes

The first jet points towards Earth, which is why it appears particularly bright to us and has been known for a long time. The second jet is oriented differently and was therefore more difficult to detect. Over a period of just a few weeks, the astronomers observed significant changes: The second jet starts behind the larger black hole and moves counterclockwise around it. This process repeats itself. "Evaluating the data felt like being on a ship. The entire jet system is in motion. A system of two black holes can explain this: The orbital plane sways", explains Silke Britzen. On one observation day in June 2022, the radiation emitted by the system reached us on such a crooked path that it appeared ring-shaped – a so-called Einstein ring. The most likely explanation is that the system was perfectly aligned towards us. Gravitational lensing by the known black hole in front then shaped the light of the second jet behind it.

By analysing the progression over time and recurring patterns in the brightness of the jets, the researchers were able to deduce that the two black holes orbit each other with a period of approximately 121 days. They are about 250 to 540 times farther apart than the distance between Earth and the Sun – tiny for such extreme objects with masses of between 100 million and a billion times that of the Sun. Depending on their actual masses, the distance between them could decrease so rapidly that they could merge in as short as 100 years.

Countdown to the finale

Due to the great distance between Mrk 501 and Earth, even the most advanced observation methods cannot image the two black holes as separate objects. Not even the Event Horizon Telescope (EHT), which provided us with the first images of black holes in 2019 and 2022, is powerful enough. The increasingly shrinking orbit of the pair in Mrk 501 will therefore not be directly observable. Nevertheless, scientists expect clear evidence of the ever-decreasing separation between the two black holes: The system should emit gravitational waves at very low frequencies, which could be detected using pulsar timing arrays (PTAs).

Supermassive black hole binaries (SMBHBs) are already the favoured explanation for the observed gravitational wave background, for which evidence was found in 2023 by the European Pulsar Timing Array and others. Mrk 501 is now a prime candidate for attributing gravitational wave emission measured with PTAs to a specific supermassive black hole binary. “If gravitational waves are detected, we may even see their frequency steadily rise as the two giants spiral toward collision, offering a rare chance to watch a supermassive black hole merger unfold”, notes co-author Héctor Olivares.

The graphical depiction shows the central region of the galaxy Mrk 501 at a frequency of 43 gigahertz on three different days. The contours indicate the intensity of the emission, while the grey circles mark bright regions within the jet, identified through model calculations. One can track the movement of the jets by following the movement of these regions. The previously known jet (Jet 1, orange guide line) pointing towards Earth is clearly visible. The newly discovered second jet (Jet 2, blue) changed its appearance within a few weeks. Both particle streams originate close to each other in the core of the galaxy. The position of the black hole (BH) associated with Jet 1 is marked with an arrow. © S. Britzen



Additional Information
The following scientists affiliated to the MPIfR are co-authors of this publication: Silke Britzen, Frédéric Jaron und Nicholas Roy McDonald.


Contacts:

Priv.-Doz. Dr. Silke Britzen
Tel: +49 228 525-280
sbritzen@mpifr-bonn.mpg.de
Max Planck Institute for Radio Astronomy, Bonn

Dr. Héctor Raúl Olivares Sánchez
h.sanchez@ua.pt
Mathematics Department and Center for Research and Development in Mathematics and Applications of the University of Aveiro

Dr. Nina Brinkmann
Press and Public Relations
Tel: +49 228 525-399
brinkmann@mpifr-bonn.mpg.de/a>
Max Planck Institute for Radio Astronomy, Bonn


Original publication

 Britzen, S. et al.:
Detection of a second jet within the nuclear core of Mrk 501
Monthly Notices of the Royal Astronomical Society (2026)

DOI


Parallel press release from the University of Aveiro (Portuguese)

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Friday, April 10, 2026

A pair of planet-forming discs

Image Description: Two images of protoplanetary discs side-by-side. The left image shows a dark horizontal band covering the star, with broad, colourful, conical outflows above and below it, and a narrow jet pointing directly up and down from the star. The right image shows the star within a yellow dusty disc, with scattered dust creating purple lobes above and below the disc. Each is on a black background with several galaxies or stars around it. Credit: ESA/Webb, NASA & CSA, ESA/Hubble, ALMA (ESO/NAOJ/NRAO), G. Duchêne, M. Villenave Hi-res Tif

This month’s NASA/ESA/CSA James Webb Space Telescope Picture of the Month offers us a two-for-one on brand new stars – with some potential planets thrown in as well!

This visual highlights Webb's views of the protoplanetary discs Tau 042021 (left) and Oph 163131 (right), otherwise known by the catalogue numbers 2MASS J04202144+2813491 and 2MASS J16313124-2426281, respectively. Tau 042021 is situated around 450 light-years from Earth in the constellation Taurus, while Oph 163131 lies about 480 light-years away in Ophiuchus.

Protoplanetary discs like these appear around stars that have recently been born. When a clump of gas inside a larger molecular cloud collapses to form a star, unused gas and dust is left orbiting the star in a thick disc. Over time, this dust too collides and collapses, slowly forming planetesimals which can, in turn, develop into planets. The planetesimals which can’t make the jump to being a fully-fledged planet are left behind as asteroids and comets orbiting the star. Gas that isn’t consumed by this process is blown away by the new star’s radiation over the course of tens of millions of years, ending the protoplanetary disc. This is how our own Solar System formed in the distant past, creating the asteroids, comets, gas giants and terrestrial planets we know today. By observing other protoplanetary discs at a much earlier age, we can work out how this process worked for our own Solar System, and how the different kinds of planets we see across the galaxy could have formed.

The unique feature these two objects have in common is that, as we see them from our vantage point with Webb, they are oriented with the edge of the disc facing us. This means that the bright light from the young star in the centre is mostly blocked, and we see the fine dust that has risen out of the disc as a nebula above and below the disc, lit by reflected light from the star. Not only is this a beautiful sight, producing these images that resemble rainbow-coloured spinning tops in space, it’s essential for studying how these planet-forming discs are composed. The distribution of dust in the disc, both within it and above or below it, strongly affects where and how planets can form.

These images were created using data from Webb’s NIRCam and MIRI instruments, as part of Webb programme #2562 (PI F. Ménard, K. Stapelfeldt). With the broad infrared sensitivity of these two cameras, Webb can track dust grains of different sizes across the disc. The red, orange and green colours of the discs in these images indicate various sizes of dust grains as well as molecules such as hydrogen (H2), carbon monoxide (CO) and polycyclic aromatic hydrocarbons (PAHs).

Both images also feature data from the NASA/ESA Hubble Space Telescope, which shows visible light, mainly from the central star reflected off the fine, floating dust. The image of Oph 163131 also includes observations from the Atacama Large Millimeter/submillimeter Array (ALMA). Where Hubble and Webb each image tiny dust grains only micrometres across, ALMA sees larger dust grains that are about a milimetre in size, which are concentrated in the central plane of the disc. This can create the right conditions for the grains to continue to grow and potentially form planets. Indeed, the ALMA data for Oph 163131 shows a gap in the inner disc, which may already be evidence of a planet forming and clearing out the dust around it.



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Thursday, April 09, 2026

Signs of a Supermassive Black Hole Merger in NGC 4486B

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This Hubble Space Telescope image shows two galaxies in the process of merging. When two galaxies merge, their respective supermassive black holes can form a binary that eventually merges as well. Credit: ESA/Hubble & NASA, W. Keel, SDSS; CC BY 4.0

The galaxy NGC 4486B appears calm and collected, but its center may have been roiled by a recent merger of supermassive black holes. New modeling explores the stellar dynamics that support this hypothesis.

Kinematic maps of NGC 4486B showing the locations of the two peaks of its double nucleus.
Adapted from Tahmasebzadeh et al 2026

Strange Center

Astronomers have known for 30 years that NGC 4486B, a compact elliptical galaxy near the center of the Virgo cluster, has a double nucleus. More recently, JWST observations revealed that the galaxy houses a black hole of 360 million solar masses, which is unusually large compared to the galaxy’s stellar mass of 9 billion solar masses. The two nuclei are roughly 40 light-years from the apparent center of the galaxy, and the black hole also appears to be offset from the galactic center by 20 light-years.

Now, a team led by Behzad Tahmasebzadeh (University of Michigan; Villanova University) has investigated the possibility that NGC 4486B’s double nucleus and off-center black hole can be traced to the aftermath of a supermassive black hole merger.

Estimated black hole kick magnitude as a function of the initial mass ratio of the black hole binary.
Tahmasebzadeh et al. 2026

Simulating Kinematics

In this scenario, the In
In this scenario, the black hole is displaced from the galaxy’s center because of a “kick” it received when it underwent a merger. The double nucleus is a sign of an eccentric nuclear disk: a central disk of stars on aligned elliptical orbits created when merging supermassive black holes disturb an initially orderly disk of stars.

Tahmasebzadeh and collaborators performed dynamical modeling to test this hypothesis and understand what types of stellar orbits would be necessary to reproduce the kinematic signature of NGC 4486B’s center seen with JWST. The simulation results called for a blend of prograde and retrograde stellar orbits that closely resembled what is expected for an eccentric nuclear disk. From the properties of the simulated stellar disk, the team estimated that the mass ratio of the merging black holes was >0.15.

To explore this scenario further, the team carried out N-body simulations of the post-merger black hole’s behavior. These simulations showed that after being booted from the galactic center by the post-merger kick, the black hole returns to the center quickly — within 10–80 million years, depending on the kick strength. Because NGC 4486B’s supermassive black hole is notably off center, this suggests that the merger occurred recently.

Galaxy Merger Versus Black Hole Merger

Tahmasebzadeh’s team tested two other theories that could explain the appearance of NGC 4486B’s nucleus: dynamical buoyancy and a pre-merger supermassive black hole binary. Neither of these scenarios could reproduce the offsets seen in the center of the galaxy.

The team noted that NGC 4486B appears to be in equilibrium, with no sign of a recent merger that could have plunked a second supermassive black hole into the galaxy. How can this fact be reconciled with the evidence for a recent black hole merger? Turning again to simulations, the team found that if the black hole binary’s orbit was aligned with the galaxy’s rotation, the binary could have become trapped in a resonance that greatly delayed the merger of the black holes. This makes it possible that NGC 4486B underwent a galaxy merger in the distant past, but its central black hole merged only recently, leaving signs of a long-ago merger that has otherwise faded from view.

By Kerry Hensley

Citation
“JWST Observations of the Double Nucleus in NGC 4486B: Possible Evidence for a Recent Binary SMBH Merger and Recoil,” Behzad Tahmasebzadeh et al 2026 ApJL 1001 L14. doi:10.3847/2041-8213/ae52ef


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Wednesday, April 08, 2026

JWST Spies Once-hidden Treasures in the W51 Starbirth Crèche

A mid-infrared view of M51 provided by the James Webb Space Telescope's MIRI instrument. Swirls of interstellar gas are being illuminated by massive young newborn stars.Credit: NASA, ESA, CSA, Yoo & Ginsburg (UF). Image processing: A Pagan (STScI)

Star formation is a dramatic and complex process that erupts throughout the Universe. Yet, a lot of that action gets hidden by clouds of gas and dust. That's where observatories such as the James Webb Telescope JWST and the Atacama Large Millimeter Array (ALMA) come in handy. They use infrared light and radio waves respectively, to pierce the veil surrounding the process of starbirth.

A team led by University of Florida doctoral candidate Taehwa Yoo recently used to JWST to make observations of the giant Milky Way starbirth region Westerhout 51 (W51). It lies about 17,000 light-years away from Earth in the direction of the constellation Sagittarius. The images and data they collected revealed many fine details of the star-formation activity going on there. “With optical and ground-based infrared telescopes, we can’t see through the dust to see the young stars,” said Adam Ginsburg, Ph.D., a professor of astronomy at UF. “Now we can.”

An overview of W51A region. The composite image is produced by combining NIRCam F360M (blue), F410M (green), and MIRI F560W (red) on JWST. The north and east directions in ICRS coordinates are marked as arrows at the upper left corner. Courtesy Yoo, et al.

Despite the impressive images and data, some aspects of star birth remain hidden away behind clouds too dense even for JWST to pierce. The team compared their JWST images to observations of the same region made by the ALMA, and found that only a fraction of stars are detectable by both telescopes. The observations that JWST did make, however, showed a lot of detail in the structures it could see. And that provides astronomers with new insights into the starbirth process. "Because of James Webb, we can see those hidden, young massive stars forming in this star-forming region," Yoo said. "By looking at them, we can study their formation mechanisms."

Cutout images of specific regions in W51. (a) A dust filament around W51-E. (b) W51-IRS2 protocluster. (c) Cometary objects around W51-IRS2 (these are globules of dust that look like comets, sculpted by radiation from nearby stars). (d) W51-E protocluster. (e) A bar at the edge of IRS1 H II region. (An HII region is a cloud of mostly hydrogen gas from which stars can form.) (f) W51 IRS1 H II region shell structure. (g) W51b1 H II region. (h) W51b2 H II region and YSOs. (i) W51e7 H II region. (j) W51c1 H II region. (k) and (l) Newly discovered H II regions. Courtesy Yoo, et al.

Digging Into W51's Starbirth Activity

W51 is divided into several regions of enhanced star formation. As part of the observations, JWST zeroed in on the W51A region, the youngest starbirth crèche in the area. Multiple clouds of ionized gas and warm dust exist there, with some of the dust arranged in filaments. The science team also spotted a good example of a cavity around one of the newborn stars, which indicates that the star is "eating away" at its birthplace. They also studied giant gas bubbles of gas, dark dust filaments (which are likely still-hidden crèches), cometary objects, and protostellar jets streaming away from protostellar objects. Each of these are part of the starbirth process.

The team focused on the massive protoclusters called W51-E and W51-IRS2, using the Near Infrared Camera (NIRCAM) and the Mid-infrared Instrument (MIRI). Most of the stars they were able to observe are still accreting material and hadn't yet reached their full masses. Some have only formed in the past million years or so.

Yoo's group estimates there are about 10,000 solar masses of stars in W51A. Many are very young, massive stars, and not a lot is known about their earliest infancy, which is what fascinates astronomers today. In some areas, those remain hidden by too-thick clouds of gas and dust. Luckily, W51A has a lot to offer based on previous studies made by the Atacama Large Millimeter/submillimeter Array (ALMA). That radio array in Chile detected over 200 compact sources referred to as “PPOs (Pre/Protostellar Objects)” in the region. These are places where stars are actively forming or will start to form in the relatively near future. Astronomers want to know what kickstarts the process of star formation in regions like these, and what stages occur as massive young stars begin to form.

Combined observations from JWST and ALMA show the location of protocluster regions where multiple stars are forming. The locations of the matching sources are marked in the upper panel with the background image of F162M, F210M, and F480M filters on JWST. In the lower panels, W51-E and W51-IRS2 protocluster regions are zoomed in with the background image of the JWST NIRCam filters and ALMA 1.3 mm image combined. Courtesy Yoo, et al.

Starbirth Stages

In a general sense, astronomers know the overall process of starbirth: clouds of gas and dust condense and form hot cores called "young stellar objects." These are where the future star will be born. After a period of accretion, the star reaches a point where it begins fusing hydrogen to helium in its core. That's the point where the star is born. Before that, the star begins as that hot core, and also blows material away from itself via a superheated jet. High-mass stars born like this obviously affect their environment, especially in their birth crèches. They interact with neighboring clouds of gas, which affects the formation of sibling stars in the same region. The radiation from those high-mass stars can even go so far as to rip apart the clouds of gas. That chokes off the available material for new stars to form. From the JWST images and data, it's clear that each of those steps is in process in the W51A cloud.

In a recent paper in the Astrophysical Journal (noted below), Yoo and the team point out that several hot cores with rich chemistry associated with massive protostars exist in W51A. These are very likely sites of maser emissions from several varieties of molecules in the gas clouds crèches, including OH (hydroxide), CH3OH (methanol), SiO (silicon monoxide), NH3 (ammonia), and CS (carbon monosulfide). The presence of these masers acts as a tracer for dense molecular clouds where stars are expected to form (if they aren't doing so already).

In addition to the hot cores that indicate the very early stellar birth process, the team also observed at least one "knot" of emission from a protostellar object. It indicates ionized iron and hydrogen within the cloud. They think it's from a jet streaming from a hot young star that's heating up and affecting the nearby interstellar medium.

This latest look at W51 with JWST gives astronomers a much better idea of what different stages of starbirth look like, stages that are normally hidden from optical observations. The quality of the JWST data revealed more information and showed new structures in the area that astronomers can now use to more fully explain the process of starbirth. “They are not the first photos of this region, but they are the best,” said Ginsburg. “They’re so much better that they essentially are brand new photos. Every time we look at these images, we learn something new and unexpected."

By Carolyn Collins Petersen - April 06, 2026 01:04 AM UTC | Stars



For More Information

Researchers Use JWST to Reveal Hidden Details of W51 Star Formation

A JWST NIRCam/MIRI view of the W51A high-mass star-forming region


Carolyn Collins Petersen

Carolyn Collins Petersen is a long-time science writer and former astronomy researcher. She writes about astronomy and space exploration and has written 8 books, countless articles, more than 60 documentaries for planetarium star theaters, and exhibits for Griffith Observatory, NASA/JPL, the California Academy of Sciences, the Shanghai Astronomical Museum, and the Lowell Observatory Dark Sky Planetarium. She is CEO of Loch Ness Productions. You can email Carolyn here.

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