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


Saturday, July 04, 2026

Action! NSF–DOE Vera C. Rubin Observatory Begins Capturing the Greatest Cosmic Movie Ever Made

PR Image noirlab2616a
Ocean of Stars

PR Image noirlab2616b
The depth of NSF–DOE Rubin’s LSST

PR Image noirlab2616c
Ocean of Stars excerpts

PR Image noirlab2616d
NSF–DOE Rubin’s LSST coverage

PR Image noirlab2616e
NSF–DOE Vera C. Rubin Observatory by the numbers

PR Image noirlab2616f
NSF–DOE Rubin’s Legacy Survey of Space and Time

PR Image noirlab2616g
NSF–DOE Rubin’s Ocean of Stars field in the constellation Lupus

PR Image noirlab2616h
NSF–DOE Vera C. Rubin Observatory by the numbers (Spanish)

PR Image noirlab2616i
NSF–DOE Rubin’s Legacy Survey of Space and Time (Spanish)



Videos

A Week in the Life of NSF–DOE Rubin LSST
PR Video noirlab2616a
A Week in the Life of NSF–DOE Rubin LSST

The depth of NSF–DOE Rubin’s LSST
PR Video noirlab2616b
The depth of NSF–DOE Rubin’s LSST

How NSF–DOE Rubin maps the Universe every night
PR Video noirlab2616c
How NSF–DOE Rubin maps the Universe every night

Pan on NSF–DOE Rubin’s Ocean of Stars
PR Video noirlab2616d
Pan on NSF–DOE Rubin’s Ocean of Stars

A Week in the Life of NSF–DOE Rubin LSST (fulldome fisheye)
PR Video noirlab2616e
A Week in the Life of NSF–DOE Rubin LSST (fulldome fisheye)

A Week in the Life of NSF–DOE Rubin’s LSST (no annotations)
PR Video noirlab2616f
A Week in the Life of NSF–DOE Rubin’s LSST (no annotations)

Zooming into NSF–DOE Rubin’s Ocean of Stars
PR Video noirlab2616g
Zooming into NSF–DOE Rubin’s Ocean of Stars

A Week in the Life of NSF–DOE Rubin’s LSST (vertical)
PR Video noirlab2616h
A Week in the Life of NSF–DOE Rubin’s LSST (vertical)



The 10-year Legacy Survey of Space and Time has officially started, marking the beginning of a new era in astronomy and astrophysics

The wait is over: NSF–DOE Rubin Observatory, funded by the U.S. National Science Foundation and the U.S. Department of Energy’s Office of Science, is now capturing the cosmos in unprecedented detail, transforming the way we study the dynamic Universe.

From a mountaintop in Chile, under clear dark skies, NSF–DOE Vera C. Rubin Observatory has begun the revolutionary Legacy Survey of Space and Time (LSST). The ten-year survey is Rubin’s signature campaign to create the most comprehensive, cinematic record of the Universe in history.

Rubin Observatory is a U.S. government facility jointly operated by NSF NOIRLab and DOE’s SLAC National Accelerator Laboratory. NOIRLab is managed by the Association of Universities for Research in Astronomy (AURA).

Over the next ten years, Rubin will relentlessly observe the entire southern sky every few nights to create an ultra-wide, ultra-high-definition time-lapse record of our Universe. This long-awaited milestone is the culmination of years of effort by thousands of people around the world. It follows the celebratory Rubin First Look event that took place in June 2025, which was followed by final commissioning work, an operational readiness review, and the beginning of the alert stream.

“Today, we begin filming the greatest cosmic movie ever made,” says Brian Stone, performing the duties of the NSF Director. “This moment reflects decades of vision, innovation, and the power of federal investment in science through the U.S. National Science Foundation and the Department of Energy. Every night, NSF–DOE Rubin Observatory will expand the frontiers of knowledge and strengthen America's global leadership in science and innovation.”

“With the launch of the ten-year Legacy Survey of Space and Time, NSF–DOE Rubin Observatory is opening a new window on the Universe. It is embarking on a mission that will redefine modern cosmology and astrophysics,” says Darío Gil, Under Secretary for Science at the U.S. Department of Energy. “With its world-class design and tools, Rubin Observatory will capture the dynamic nature of our cosmos and reveal unimagined insights into our Universe’s biggest mysteries, from our own Solar System to the very structure of the Universe. By seeking to understand the enigmatic phenomena of dark energy and dark matter, we are not just observing the stars; we are striving to grasp the fundamental laws that govern our existence.”

“It is amazing and humbling to be here at this time and place as we start the Legacy Survey of Space and Time, after more than two decades of incredible work by our dedicated team,” says Bob Blum, Director of Rubin Observatory at NSF NOIRLab. “Rubin Observatory is for everyone; the LSST will change how we do astronomy and astrophysics, allowing researchers anywhere to participate in cutting-edge science.”

“It’s taken 20 years of hard science, engineering, and more to get to the point where we can call ‘action’ as we start rolling on this blockbuster movie of the Universe,” says Phil Marshall, Deputy Director of Rubin Operations for SLAC. “Millions of alerts in just the last couple of months show that Rubin is up and running as a discovery machine. Now we’re putting it all together.”

“The decision to officially begin the LSST was made after a period of system optimization and a careful operational review of technical readiness, data system performance, and scientific validation,” says Željko Ivezić, Head of LSST. Important factors that played a role in this decision included image quality, effective survey speed, system uptime and reliability, and calibration accuracy.

Rubin Observatory’s unique design combines enormous light-collecting power, the ability to move rapidly across the sky, and a wide field of view. Its 3200-megapixel camera — the largest digital camera in the world — is now capturing a new, detailed image approximately every 40 seconds. Operating with this speed and sensitivity, Rubin functions as a unified, well-tuned system capable of catching faint objects and fleeting events with remarkable reliability and consistency every night. Visit rubinobservatory.org to follow the status of the Rubin in real time (and visit the real-time Alert Dashboard).

Rubin is bringing the Universe to life, illuminating a treasure trove of discoveries: pulsating stars, supernova explosions, the fossil record of galaxies, clues to the mysteries of dark energy and dark matter, and entirely new phenomena we’ve never seen before. Some cosmic processes unfold slowly, unpredictably, or incredibly rarely, which is why a ten-year survey is essential. By returning to each point in the sky about 800 times over a decade, Rubin data is providing the scientific community with deep, time-rich views needed to uncover subtle events, capture moving objects, and study the accelerating expansion of the Universe.

Not only is Rubin helping to unlock the mysteries of the distant Universe, it is also the most powerful Solar System discovery machine ever built. By taking about a thousand images every night, Rubin is compiling an astonishingly detailed census of our Solar System, including millions of asteroids and comets. In just a month and a half, during early optimization surveys, Rubin discovered over 11,000 never-before-seen asteroids, including 33 near-Earth objects and 380 trans-Neptunian objects [1].

Rubin will also advance opportunities for multi-messenger astronomy, which is the study of cosmic events using multiple signals such as light, gravitational waves, and cosmic rays. The observatory’s rapid, color-rich observations of transients such as stellar explosions, actively feeding black holes, and collisions between compact objects will guide telescopes around the world to follow up on these fleeting events.

Each night, Rubin is collecting approximately ten terabytes of data and producing as many as seven million alerts of changes in the night sky. These alerts stream to alert brokers — automated systems that sort and classify these changes so scientists can act quickly.

When the LSST is complete, the final dataset will contain billions of objects with trillions of measurements, all accessible through regular data releases. This is the first time so much astronomical data will be available to so many people, opening the door to new kinds of discovery by both scientists and the public. Rubin invites anyone in the world to engage with its data and explore the dynamic Universe in ways never before possible.




Notes

[1] One of the newly discovered asteroids is the fastest-spinning asteroid larger than 500 meters (0.3 miles) ever found, and it resides in the main asteroid belt.



More information

NSF–DOE Vera C. Rubin Observatory, funded by the U.S. National Science Foundation and the U.S. Department of Energy’s Office of Science, is a groundbreaking new astronomy and astrophysics observatory on Cerro Pachón in Chile. It is named after astronomer Vera Rubin, who provided the first convincing evidence for the existence of dark matter. Using the largest camera ever built, Rubin will repeatedly scan the sky for 10 years to create an ultra-wide, ultra-high-definition, time-lapse record of our Universe.

NSF–DOE Vera C. Rubin Observatory is a joint initiative of the U.S. National Science Foundation (NSF) and the U.S. Department of Energy’s Office of Science (DOE/SC). Its primary mission is to carry out the Legacy Survey of Space and Time, providing an unprecedented data set for scientific research supported by both agencies. Rubin is operated jointly by NSF NOIRLab and SLAC National Accelerator Laboratory. NSF NOIRLab is managed by the Association of Universities for Research in Astronomy (AURA) and SLAC is operated by Stanford University for the DOE. France provides key support to the construction and operations of Rubin Observatory through contributions from CNRS/IN2P3. The Science and Technology Facilities Council supports the wide range of UK contributions to Rubin operations provided through the LSST:UK Science Centre programme. Rubin Observatory is privileged to conduct research in Chile and gratefully acknowledges additional contributions from more than 40 international organizations and teams.

The U.S. National Science Foundation (NSF) is an independent federal agency created by Congress in 1950 to promote the progress of science. NSF supports basic research and people to create knowledge that transforms the future.

The DOE’s Office of Science is the single largest supporter of basic research in the physical sciences in the United States and is working to address some of the most pressing challenges of our time.

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.

SLAC National Accelerator Laboratory explores how the Universe works at the biggest, smallest and fastest scales and invents powerful tools used by researchers around the globe. As world leaders in ultrafast science and bold explorers of the physics of the Universe, we forge new ground in understanding our origins and building a healthier and more sustainable future. Our discovery and innovation help develop new materials and chemical processes and open unprecedented views of the cosmos and life’s most delicate machinery. Building on more than 60 years of visionary research, we help shape the future by advancing areas such as quantum technology, scientific computing and the development of next-generation accelerators. SLAC is operated by Stanford University for the U.S. Department of Energy’s Office of Science.

Forty-three international teams outside the U.S. and Chile are contributing to Rubin Observatory and LSST Science through the In-kind Program, in exchange for LSST data rights. These contributions are recognized in the International Data Rights Holder list, which includes all individuals nominated by their respective international programs.



Links



Contacts:

Bob Blum
Director for Operations
NSF–DOE Vera C. Rubin Observatory/NSF NOIRLab
Email:
bob.blum@noirlab.edu

Phil Marshall
Deputy Director of Operations
SLAC National Accelerator Laboratory
Email:
pjm@slac.stanford.edu

Lars Lindberg Christensen
Head of Communications, Education & Engagement
NSF NOIRLab
Email:
lars.christensen@noirlab.edu

Manuel Gnida
Head of External Communications
SLAC National Accelerator Laboratory
Email:
mgnida@slac.stanford.edu


Friday, July 03, 2026

NASA’s Webb Reveals Stars Sparking to Life in Cosmic Celebration

In infrared light, NASA’s James Webb Space Telescope reveals bright protostars in star system FS Tau and a tapestry of background galaxies. FS Tau B, the orange protostar slightly right of center, is thought to be responsible for the orange outflows amid the dusty region. Credit Image: NASA, ESA, CSA, STScI; Image Processing: Alyssa Pagan (STScI)

A comparison between the observations of FS Tau by NASA’s Hubble and James Webb space telescopes. Hubble’s visible-light view shows the star-forming region mostly obscured by thick dust. Webb sees through the dust, revealing how the protostars are shaping their surroundings. Credit Image: NASA, ESA, CSA, STScI; Image Processing: Alyssa Pagan (STScI)

An image of FS Tau captured by Webb’s NIRCam (Near-Infrared Camera), with compass arrows, scale bar, and color key for reference. Credit Image: NASA, ESA, CSA, STScI; Image Processing: Alyssa Pagan (STScI)



NASA’s James Webb Space Telescope has captured the infrared light of numerous features that previously were impossible to see beyond the thick dust of the FS Tau star system. In addition to myriad background galaxies that burst into view like fireworks for the United States’ 250th anniversary celebrations, this image flickers with a number of protostars, or baby stars that are formed from dense pockets of gas and dust. These hot, clumpy, and low-mass objects eventually will become full-fledged stars capable of burning hydrogen in their cores, like our Sun. The protostars of FS Tau are about 1 to 3 million years old, which is relatively young in cosmic scales. Our Sun, by contrast, is 4.6 billion years old.

Low-mass stars emit less radiation and have less energetic stellar winds than those with larger masses, which means they disrupt their environment at a much lower level. This makes the FS Tau region incredibly useful for studying low-mass star evolution without the same level of environmental interference seen near higher-mass stars. A pair of protostars that creates the largest diffraction pattern seen slightly to the left of center in the image, called FS Tau A, is about half the mass of our Sun.

Even though these objects are young and low-mass, they still can impact their surroundings, partially due to the outflows they emit. These outflows, seen as orange and red wisps and wide sheets, are theorized to come from FS Tau B, the protostar slightly to the right of center that has an orange diffraction pattern. As FS Tau B feeds on the surrounding dust and gas to grow, it ejects some of that matter outward. The wider outflows are thought to come from the interaction between the protostar’s magnetic field and superheated matter closest to the protostar within its accretion disk. The disk is seen as a dark band that cuts across at a 30-degree angle.

The gaps between the outflows, newly discovered in this Webb observation, add to growing evidence that protostars accrete matter in discrete episodes. In the periods where protostars gather material and increase in mass, they also eject superheated matter in different directions. In between these episodes, they are relatively quiet.

As protostars eject these outflows, they shape their surroundings. This is best shown by the prominent light-blue ridges of dust and gas near FS Tau B. These thicker regions were likely created as outflows struck and compressed matter together. The brightness of these light-blue ridges shows that the nearby protostar’s light is reflected. Moreover, Webb’s sensitivity reveals the varying textures of dust and gas across the entire region.

The range of colors seen in this observation also provides a wealth of information, specifically about where dust is and how much of it obscures the region. Light with bluer wavelengths is absorbed and scattered by dust, while redder-wavelength light is able to slip through. Therefore, background galaxies behind thicker foreground dust appear redder. Alternatively, yellow galaxies have much less dust obscuring them. The few white stars visible in this image are likely in the foreground.

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: Jul 02, 2026
Location:
NASA Goddard Space Flight Center

Contact Media:

Laura Betz
NASA’s Goddard Space Flight Center
Greenbelt, Maryland

laura.e.betz@nasa.gov

Matthew Brown
Space Telescope Science Institute
Baltimore, Maryland


Abigail Major
Space Telescope Science Institute
Baltimore, Maryland



Thursday, July 02, 2026

NASA’s Webb Studies How Planet Survived Death of its Star

Exoplanet WD 1856 b, shown in this artist’s concept, is a gas giant that orbits its star at a distance 50 times closer than Earth orbits the Sun. Observations by NASA’s James Webb Space Telescope determined the planet’s temperature and detected molecules in its atmosphere. Credit Artwork: NASA, ESA, CSA, Ralf Crawford (STScI)

NASA’s James Webb Space Telescope measured the constituents of exoplanet WD 1856 b as it passed in front of its star, finding signs of methane. WD 1856 b orbits a white dwarf star the size of Earth. As a result, the planet blocks more than half of the star’s light. Credit Illustration: NASA, ESA, CSA, Joseph Olmsted (STScI)



NASA’s James Webb Space Telescope is giving us new insight into the far-future of solar systems like our own, as the agency continues to reveal the secrets of the universe and our place in it. Billions of years ago, a Sun-like star nearing the end of its life swelled tremendously in size to become a red giant before ejecting its outer layers, leaving a hot, remnant core known as a white dwarf. As a red giant, the star should have engulfed and destroyed any nearby planets. Yet astronomers have found a Jupiter-sized exoplanet orbiting the white dwarf every 34 hours at a separation of less than 2 million miles (3 million kilometers).

To solve the mystery of how this exoplanet survived, an international team of astronomers used NASA’s James Webb Space Telescope to watch the Jupiter-sized exoplanet WD 1856 b transit its host star, measuring the planet’s temperature and detecting molecules in its atmosphere. They found the planet is significantly warmer than expected and determined how it most likely reached its very tight orbit around the white dwarf star. The results are a window into the future of planets like Jupiter after the death of the Sun, billions of years into the future.

The results published Wednesday in the journal Nature.

WD 1856 b was discovered in 2020 by scientists using NASA’s TESS (Transiting Exoplanet Survey Satellite) and the retired Spitzer Space Telescope. It orbits the white dwarf WD 1856+534, which is located about 80 light-years from Earth. “The planet is about the size of Jupiter, but the white dwarf it orbits is the size of Earth, so the planet is seven times larger than its star," said lead author Ryan MacDonald of the University of St. Andrews in the United Kingdom.

WD 1856 b orbits extremely close to its host star, a distance 50 times closer than Earth orbits the Sun. If WD 1856 b had originally been orbiting at that distance, it would have been obliterated while the star was a red giant. How did it survive the death of its host star and end up in its current position?

How big, how hot

The new study used Webb to watch the planet passing in front of its star. This transit yielded unique information about the planet’s mass, which is between four and eleven times the mass of Jupiter.

The team also was able to determine the planet’s temperature. During the transit, light from the star was partly blocked, but infrared light was reduced less than other wavelengths. The difference was infrared light emitted by the planet from its own heat. The data indicated that the planet has a temperature of about 260 degrees Fahrenheit (126 degrees Celsius) — significantly hotter than it would be if its only source of heat was the light from the white dwarf. This puzzling discovery turned out to be the key fact that proved how the planet must have reached its current orbit.

Christopher O’Connor of Northwestern University in Illinois, a co-author on the paper, was responsible for tracing the temperature of the planet back in time. O’Connor said, “The big question is how WD 1856 b ended up where it is today, and there are two theories. One is that the planet was swallowed by the host star as it was dying, and managed to survive on the inside. The other is that migration took place due to the gravitational effect of other objects in the system. The white dwarf is part of a triple star system, and the companion stars could have influenced WD 1856 b’s orbit.”

The researchers realized that there was no source of energy present to generate that heat today, so it must be residual energy from an earlier time when the planet was heated. Using models of how sub-stellar objects like WD 1856 b cool down over time, coupled with the new data from Webb, the team was able to project its temperature back in time and deduce how long ago the heating must have happened. The timing is key to determining whether the heating was from being engulfed by the red giant or occurred during an inward migration.

They concluded that the heating most likely happened between 3 and 5.5 billion years after the star became a white dwarf. In this scenario, the planet was on a wide orbit that kept it safe from the star during its destructive red giant phase, and only migrated to its present location later on. “As the planet moved inward, its interactions with the strong gravity of the white dwarf will have caused it to warm up considerably, and it has been cooling ever since,” said O’Connor.

Light from the star passing through the planet’s atmosphere also picked up information about its chemical composition. “We saw the telltale signatures of small cloud particles and hydrocarbons, most likely methane, which is the first time we have seen an atmosphere on a planet transiting a dead star,” said co-author Victoria Boehm of Cornell University. “We recently observed four more transits of WD 1856 b with Webb to take a deeper look into its atmospheric chemistry and can’t wait to see the results.”

Solar system’s possible future

In approximately five billion years, the Sun will run out of hydrogen fuel in its core and swell up more than 100 times larger than it is now into a red giant star. It will then shed its outer layers and end its life as a white dwarf star. Mercury, Venus, and possibly the Earth will be destroyed by the red giant. However, the fate of the more distant planets, particularly the gas giants, is unclear. Finding and studying planets in orbit around the remnants of Sun-like stars after their death is a means of learning what might happen in our own solar system in the far future.

“We’re used to looking back in time when we use telescopes, but this is the first time we have been able to look forward to what might happen to the outer planets around the remnant of a Sun-like star,” said MacDonald. “It’s like using a time machine to peer into the distant future of our solar system.”

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: Jul 01, 2026
Location:
NASA Goddard Space Flight Center

Contact Media:

Laura Betz
NASA’s Goddard Space Flight Center
Greenbelt, Maryland

laura.e.betz@nasa.gov

Bethany Downer
ESA/Webb
Baltimore, Maryland
Christine Pulliam Space Telescope Science Institute Baltimore, Maryland



Wednesday, July 01, 2026

Cosmic Eruption Caught in the Act by Submillimeter Array’s New Fastest Response System

An artist's impression of a superluminous supernova and an associated gamma-ray burst being driven by a rapidly spinning neutron star.




New semi-automated system demonstrates how the radio interferometer quickly responds to discoveries from space-based telescopes

Cambridge, MA (June 30, 2026) — On January 26, 2026, the Submillimeter Array (SMA) on Maunakea crossed an important threshold for time‑domain astronomy.

For the first time, scientists from the Center for Astrophysics | Harvard & Smithsonian (CfA) demonstrated a new rapid‑response capability at millimeter and submillimeter wavelengths, zooming in on a gamma‑ray burst (GRB) within minutes of its discovery and capturing the earliest observations of such an event ever made at these frequencies.

GRBs are the brightest explosions in the universe — brief but staggeringly immense flashes produced by jets launched in the collapse of massive stars or the merger of compact objects like neutron stars. Their initial burst is followed by a glow that X-ray and optical telescopes have long been able to chase within seconds or minutes of the event, but that millimeter-wave telescopes have historically lagged behind in observing.

That changed in January of this year, when the SMA rapidly responded to an automated alert from NASA’s Neil Gehrels Swift Observatory, which detected a flash of gamma rays. The sequence played out almost entirely without human intervention. Within 90 seconds, the on-duty operator had been alerted. Within four minutes, the telescope was moving to start observations.

"It was an incredible thing to watch in real time," said Garrett Keating, an astrophysicist at CfA and Deputy Director of the SMA, who led the rapid-response effort. "Being able to react and process data this quickly is a big departure from how SMA usually operates, but it was absolutely critical for capturing an event where minutes matter. This was the first time we had the full system online. We learned a lot from the experience, and think we can get the response time down to as little as two to three minutes."

Within thirteen minutes, the telescopes were on target, and a separate automated analysis was already generating images of the explosion in near real-time.

“With interferometry, we don’t get direct images from the telescope,” explained Ranjani Srinavasan, interim director of the SMA. “Usually that process takes a long time.”

The response time is roughly two orders of magnitude faster than the typical response time for millimeter and submillimeter telescopes.

“The SMA’s new capability is a game-changer for the field,” said Edo Berger, professor of astronomy at Harvard and a co-author of the study.

Follow‑up observations two days later showed that the source had faded, strengthening the case that SMA had indeed captured a transient afterglow rather than a steady background galaxy.

“This new capability opens a unique window into the physics behind some of the most powerful stellar explosions,” said Tanmoy Laskar, Assistant Professor of Physics and Astronomy at the University of Utah and a coauthor of the study. “With the SMA, we can now probe the structure and composition of the ejecta in unprecedented detail, bringing us closer to understanding how these explosions launch their powerful jets.”

The fast observations mark the launch of the SMA Sub/millimeter Program to Rapidly Investigate Novel Time‑domain Sources (SMA SPRINTS), a program designed to use the SMA and its wideband upgrade, called wSMA, to provide quick, sensitive and flexible follow‑up of transient events across the time‑variable sky.

The goal is to be ready as new facilities such as the Rubin Observatory’s Legacy Survey of Space and Time (LSST) and, later, the Roman Space Telescope, begin sending large numbers of alerts to the astronomy community.

The successful demonstration is published today in Astrophysical Journal Letters. Co-authors include Peter Blanchard, Mark Gurwell, Joshua Lovell, Ramprasad Rao, and Peter Willians, all from CfA, Anna Ho from Cornell University, Kate Alexander from the University of Arizona, Tarraneh Eftekhari from Northwestern University, and Chloe Xu from the Massachusetts Institute of Technology.




About the Center for Astrophysics | Harvard & Smithsonian

The Center for Astrophysics | Harvard & Smithsonian is a collaboration between the Smithsonian Astrophysical Observatory and the Harvard College Observatory designed to ask, and ultimately answer, humanity’s greatest unresolved questions about the universe.


Monday, June 29, 2026

Galaxy Pair NGC 3504 and NGC 3512

Galaxy Pair NGC 3504 and NGC 3512

Detail: Low Res. (800 KB) / Mid. Res. (2.6 MB) / High Res. (6.4 MB)

This striking pair of galaxies lies in the constellation Leo against a backdrop of distant galaxies. The barred spiral galaxy NGC 3504 is seen on the right, while the spiral galaxy NGC 3512 appears on the left. Although the two galaxies are thought to be physically close to one another, no clear evidence of ongoing gravitational interaction has yet been found.

NGC 3504 features a prominent ring with active star formation surrounding its central bar. Classified as a starburst galaxy, it provides an excellent laboratory for exploring the connection between bar structures and an exceptionally high rate of star formation.

By contrast, NGC 3512 is distinguished by its intricate, branching spiral arms. Although both are spiral galaxies, the two display remarkably different morphologies, making this an especially intriguing galactic pair. Credit: NAOJ; Image provided by Masayuki Tanaka

Distance from Earth: 80 million light-years
Instrument: Hyper Suprime-Cam (HSC)