Open Cluster Bochum 14 as imaged by Rubin

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This image shows the open star cluster Bochum 14, captured by the NSF–DOE Vera C. Rubin Observatory. Open clusters like this are made up of stars that formed together from the same cloud of gas and dust, remaining loosely bound as they drift through the Milky Way. Observations like this help astronomers study how stars are born, evolve, and spread out over time. With its powerful wide-field view, the Rubin Observatory is set to reveal countless scenes like this across the southern sky.

Image Credit: RubinObs/NOIRLab/SLAC/NSF/DOE/AURA

Image enhancement: Jean-Baptiste Faure

The Virgo Cluster deeply imaged by Rubin

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Introducing the first riches from NSF–DOE Vera C. Rubin Observatory's cosmic treasure chest, a wealth of data that will help scientists make countless new discoveries about our Universe. This image exposes a Universe teeming with stars and galaxies – transforming seemingly empty, inky-black pockets of space into glittering tapestries for the first time. Only Rubin can quickly produce such large images with this much color and richness. Here, Rubin's view is focused on the southern region of the Virgo Cluster, about 55 million light-years away from Earth and the nearest large collection of galaxies to our own Milky Way.

The image offers a stunning variety of objects – from bright stars ranging from blue to red in color, to nearby blue spiral galaxies, to distant red galaxy groups – demonstrating the broad range of science made possible by Rubin data. During the 10-year Legacy Survey of Space and Time, scientists around the world will access Rubin’s treasure trove of data to address questions like: How did the Milky Way form? What makes up the 95% of the Universe we can’t see? What will a detailed inventory of Solar System objects reveal? What will we learn from watching hundreds of millions of changes in the night sky over 10 years?

Apart from a few foreground stars in our own Milky Way, the myriad specks of light captured here make up a rich tapestry of about 10 million galaxies – just 0.05% of the roughly 20 billion galaxies Rubin will image during its 10-year Legacy Survey of Space and Time (LSST). By the end of the survey, Rubin will have revealed this level of detail across the entire southern sky.

In addition to showcasing the richness and variety of celestial light in (this area), this deep, 15-square-degree image provides a sample of the way Rubin will observe during the main survey. Each individual exposure taken by Rubin Observatory covers 10 square degrees, (about 45 full moons). Combining multiple exposures of the same place on the sky – taken at different times and with different color filters – reveals extremely faint details that wouldn't be captured in a single exposure. The 1185 exposures combined to make this image were taken over a period of just 7 nights. Rubin Observatory is the only astronomical tool in existence that can assemble an image this wide and deep so quickly.

The bright stars scattered throughout this image belong to our home galaxy. By tracking their positions, brightness, and for some, even their motion over time, Rubin will help map the Milky Way in extraordinary detail – revealing its structure, history, and how it has evolved over time. With observations of never-before-seen stellar streams, dwarf galaxies, and more, Rubin data will help scientists investigate the dynamic past of our cosmic neighborhood.

In Rubin Observatory's Skyviewer tool, you can use the "display" setting to toggle between a view with and without asteroids, which appear as multicolored streaks. These moving asteroids in our Solar System were captured by Rubin's fast system at a different location in each exposure, and this is how they look when the exposures are combined. Rubin's wide field and frequent imaging make it uniquely capable of detecting and tracking asteroids, comets, and distant trans-Neptunian objects – building a detailed inventory of our Solar System and helping protect Earth by alerting scientists to potentially hazardous objects.

This image also offers a starting point for watching the ever-changing sky. Rubin will return to this same region many times over the coming decade, catching brief but important events like supernova explosions and the flares from stars as they are consumed by hungry black holes. Rubin's software will automatically compare new images to templates built from previous images, identifying up to 10 million changes each night and providing insight into short-lived cosmic phenomena and objects in motion.

On the largest scales, scientists will use Rubin's observations of galaxies like those seen here to investigate two of the Universe's biggest mysteries: dark matter and dark energy. By mapping the shapes and distributions of galaxies over time, scientists can infer the underlying structure of dark matter and observe how the expansion of the Universe is being influenced by dark energy.

The image was captured by Rubin Observatory using the 3200-megapixel LSST Camera – the largest digital camera in the world. Rubin Observatory will scan the sky every night for 10 years, creating an ultra-wide, ultra-high-definition, time-lapse record of our Universe.

Image Credit: NSF–DOE Vera C. Rubin Observatory/NOIRLab/SLAC/AURA

Image enhancement: Jean-Baptiste Faure

Open Cluster M21 as seen by Rubin

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Messier 21 or M21, also designated NGC 6531 or Webb's Cross, is an open cluster of stars located to the north-east of Sagittarius in the night sky, close to the Messier objects M20 to M25 (except M24). Here, it is imaged by NSF–DOE Vera C. Rubin Observatory. It was discovered and catalogued by Charles Messier on June 5, 1764. This cluster is relatively young and tightly packed. A few blue giant stars have been identified in the cluster, but Messier 21 is composed mainly of small dim stars. With a magnitude of 6.5, M21 is not visible to the naked eye; however, with the smallest binoculars it can be easily spotted on a dark night. The cluster is positioned near the Trifid Nebula (NGC 6514), but is not associated with that nebulosity. It forms part of the Sagittarius OB1 association.

This cluster is located 1,205 pc away from Earth with an extinction of 0.87. Messier 21 is around 6.6 million years old with a mass of 783.4 M☉. It has a tidal radius of 11.7 pc, with a nucleus radius of 1.6±0.1 pc and a coronal radius of 3.6±0.2 pc. There are at least 105±11 members within the coronal radius down to visual magnitude 15.5, including many early B-type stars. An estimated 40–60 of the observed low-mass members are expected to be pre-main-sequence stars,[8] with 26 candidates identified based upon hydrogen alpha emission and the presence of lithium in the spectrum. The stars in the cluster do not show a significant spread in ages, suggesting that the star formation was triggered all at once.

Image Credit: RubinObs/NOIRLab/SLAC/NSF/DOE/AURA

Image enhancement: Jean-Baptiste Faure

Lenticular Galaxy NGC 7722

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For this picture from the Hubble Space Telescope, we have a sight of an uncommon galaxy with a striking appearance. This is NGC 7722, a lenticular galaxy located about 187 million light-years away in the constellation Pegasus.

A "lenticular", meaning "lens-shaped", galaxy is a type that sits in between the more familiar spiral galaxies and elliptical galaxies. It is also less common than these – partly because when a galaxy has an ambiguous appearance, it can be hard to determine if it is actually a spiral, actually an elliptical galaxy, or something in between. Many of the known lenticular galaxies sport features of both spiral and elliptical galaxies. In this case, NGC 7722 lacks the defined arms of a spiral galaxy, while it has an extended, glowing halo and a bright bulge in the center similar to an elliptical galaxy. Unlike elliptical galaxies, it has a visible disc – concentric rings swirl around its bright nucleus. Its most prominent feature, however, is undoubtedly the long lanes of dark red dust coiling around the outer disc and halo.

This new Hubble image, the sharpest yet taken of NGC 7722, brings the impressive dust lanes into sharp focus. Bands of dust like this are not uncommon in lenticular galaxies, and they stand out against the broad, smooth halo of light that typically surrounds lenticular galaxies. The distinctive dust lanes of NGC 7722 are thought to result from a merger with another galaxy in the past, similar to other lenticular galaxies. It is not yet fully understood how lenticular galaxies form, but mergers and other gravitational interactions are thought to play an important part, reshaping galaxies and exhausting their supplies of gas while bringing new dust.

While it doesn't host as many new, young stars as a spiral galaxy, there's still activity in NGC 7722: in 2020 it was host to the explosion of a star that could be detected from Earth. SN 2020SSF was a Type Ia supernova, an event which occurs when a white dwarf star in a binary system siphons enough mass away from its companion star that it grows unstable and explodes. These explosions output a remarkably consistent level of light: by measuring how bright they appear from Earth and comparing against how bright they really are, it's possible to tell how far away they must be. Type Ia supernovae are one of the best ways to measure distances to galaxies, so understanding exactly how they work is of great importance to astronomers.

Taken with Hubble's Wide Field Camera 3, this Hubble image was obtained as part of an observing programme (#16691, PI: R. J. Foley) that followed up on recent supernovae. SN 2020SSF is not visible in this image, as it was actually taken two years later, when the supernova had long faded. This was on purpose: the aim of the observations was to witness the aftereffects of the supernova and examine its surroundings, which can only be done once the intense light of the explosion is gone. With Hubble's clear vision, astronomers can search for radioactive material created by the supernova, catalogue its neighbours to see how old the star likely was, and look for the companion star it left behind – all from almost 200 million light-years away.

Image Credit: ESA/Hubble and NASA, R. J. Foley (UC Santa Cruz), Dark Energy Survey/DOE/FNAL/DECam/CTIO/NOIRLab/NSF/AURA

Acknowledgement: Mehmet Yüksek

Image enhancement: Jean-Baptiste Faure

Planetary Nebula PMR 1 as seen by Webb

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Two heads are better than one in the latest images from NASA's James Webb Space Telescope, which reveal new detail in a mysterious, little-studied nebula surrounding a dying star.

Nebula PMR 1 is a cloud of gas and dust that bears an uncanny resemblance to a brain in a transparent skull, inspiring its nickname, the "Exposed Cranium" nebula. Webb captured its unusual features in both near- and mid-infrared light. The nebula was first revealed in infrared light by a predecessor to Webb, NASA's now-retired Spitzer Space Telescope, more than a decade ago. Webb's advanced instruments show detail that enhances the nebula's brain-like appearance.

The nebula appears to have distinct regions that capture different phases of its evolution – an outer shell of gas that was blown off first and consists mostly of hydrogen, and an inner cloud with more structure that contains a mix of different gases. Both Webb's NIRCam (Near-Infrared Camera) and MIRI (Mid-Infrared Instrument) show a distinctive dark lane running vertically through the middle of the nebula that defines its brain-like look of left and right hemispheres. Webb's resolution shows that this lane could be related to an outburst or outflow from the central star, which typically occurs as twin jets burst out in opposite directions. Evidence for this is particularly notable at the top of the nebula in Webb’s MIRI image, where it looks like the inner gas is being ejected outward.

While there is still much to be understood about this nebula, it's clear that it is being created by a star near the end of its fuel-burning "life". In their end stages, stars expel their outer layers. It's a dynamic and fairly fast process, in cosmic terms. Webb has captured a moment in this star's decline. What ultimately happens will depend on the mass of the star, which is yet to be determined. If it's massive enough, it will explode in a supernova. A less massive Sun-like star will continue to shed layers until only its core remains as a dense white dwarf, which will cool off over eons.

Image Credit: NASA, ESA, CSA, STScI, Image Processing: Joseph DePasquale (STScI)

Image enhancement: Jean-Baptiste Faure

Barred Spiral Lenticular Galaxy NGC 1269

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This image of NGC 1269 was taken utilizing the Department of Energy-fabricated Dark Energy Camera (DECam), which is mounted on the U.S. National Science Foundation Víctor M. Blanco 4-meter Telescope at NSF Cerro Tololo Inter-American Observatory, a Program of NSF NOIRLab.

NGC 1269 is an early-type spiral galaxy located about 33 million light-years from Earth in the constellation Eridanus. A bar, a feature common to many spiral galaxies, slices through the center of the galaxy. Surrounding the galactic core are both inner and outer disks, seeming to form "wheels" around the core. Their presence is thought to be the result of a merger with another galaxy, and the inner disk is also believed to have been further shaped by density waves radiating outward from the galactic center.

Data for this image came from the archive of the Dark Energy Survey (DES), operated by the DOE and NSF between 2013 and 2019 with the specially-designed DECam. The survey sought to study the nature of the elusive dark matter by imaging hundreds of millions of galaxies. Today, the DECam is available to other scientists for use on the Blanco telescope.

Image Credit: Dark Energy Survey/DOE/FNAL/DECam/CTIO/NOIRLab/NSF/AURA

Image processing: R. Colombari & M. Zamani (NSF NOIRLab)

Image enhancement: Jean-Baptiste Faure

Barred Spiral Galaxy NGC 646 by Euclid

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Galaxy NGC 646 sparkles like a cosmic holiday garland in this new image from the European Space Agency's Euclid space telescope. This large barred spiral galaxy is located in the constellation Hydrus and was discovered in 1834 by the British astronomer John Herschel (the son of William Herschel). The galaxy is moving away from us at about 8145 km per second. It's located roughly 392 million light-years from Earth, which means its light takes hundreds of millions of years to reach us. Although this sounds very far, NGC 646 is actually quite close compared to the billions of galaxies that Euclid will observe during its six-year mission.

By the end of 2026, ESA and the Euclid Consortium will release the first year of observations, covering about 1900 square degrees of the sky (approximately 14% of the total survey area). These images will reveal hundreds of thousands of galaxies in exquisite detail, offering new insights into how galaxies form and evolve – and why barred galaxies become more common as the Universe ages.

In this image, NGC 646 appears close to a smaller galaxy to the left, called PGC 6014. They look like neighbours, but they're actually about 45 million light-years apart, with PGC 6014 at a distance of 347 million light-years from us. So, any gravitational interaction between them, if it exists, would be very weak and short-lived. Image Credit: ESA/Euclid/Euclid Consortium/NASA

Image processing by the Euclid Science Ground Segment and M. Schirmer (MPIA)

Image enhancement: Jean-Baptiste Faure