Tuesday, December 24, 2024

Strands from Cosmic Spiderweb Connect to Subaru Telescope

The Spiderweb protocluster captured by JWST
Credit: Shimakawa et al
.
Download image (1.5MB)

An international research team has used the James Webb Space Telescope (JWST) to observe massive galaxies discovered by the Subaru Telescope in a corner of the early Universe known as the Spiderweb protocluster. The JWST results confirm what had been suggested from the Subaru Telescope observations, namely that supermassive black hole activity can truncate the growth of galaxies.

The growth and evolution of galaxies is a major theme in modern astronomy. The origin of giant elliptical galaxies is one riddle. These galaxies consist entirely of old stars, so something early in their evolution must have shut off star formation in the progenitors of giant elliptical galaxies. According to one theory, the supermassive black holes at the hearts of the galaxies may play a role in determining the star formation.

An international research team has used the Subaru Telescope to observe still-forming protoclusters of galaxies that existed 10 billion years ago. The team has found that in these regions, some galaxies are still actively forming stars while others have stopped forming stars and have started to evolve into giant elliptical galaxies. The Subaru Telescope results also show that nearly half of the galaxies in these regions host a supermassive black hole actively gobbling up matter. But the data lacked the resolution to determine the relationship between star formation and black hole activity.

Now the team has used the JWST to obtain high-resolution maps of massive galaxies discovered by the Subaru Telescope in one of the protoclusters known as the Spiderweb protocluster. The results show that in the Spiderweb, galaxies with active supermassive black holes have stopped forming new stars, while conversely galaxies without active supermassive black holes are still forming new stars. These results support the theory that black hole activity determines the star formation.

“The Spiderweb protocluster has been studied by our team for more than 10 years using the Subaru Telescope and other facilities. With the new JWST data, we are now able to ‘answer the questions’ of understanding and predicting galaxy formation that we have accumulated,” remarks Rhythm Shimakawa, lead author of the paper presenting these results.




Release Information

Paper(s)

Shimakawa et al. “Spider-Webb: JWST Near Infrared Camera resolved galaxy star formation and nuclear activities in the Spiderweb protocluster at z=2.16”, in Monthly Notice of the Royal Astronomical Society, Letters, DOI: 10.1093/mnrasl/slae098



Related Link(s



Monday, December 23, 2024

Astronomers Detect Earliest and Most Distant Blazar in the Universe

VLASS J041009.05−013919.88
Credit: U.S. National Science Foundation/NSF National Radio Astronomy Observatory, B. Saxton

A groundbreaking discovery has revealed the presence of a blazar—a supermassive black hole with a jet pointed directly at Earth—at an extraordinary redshift of 7.0. The object, designated VLASS J041009.05−013919.88 (J0410−0139), is the most distant blazar ever identified, providing a rare glimpse into the epoch of reionization when the universe was less than 800 million years old. This discovery challenges existing models of black hole and galaxy formation in the early cosmos.

J0410−0139 is powered by a black hole with a mass of 700 million times that of the Sun. Multi-wavelength observations show that its radio variability, compact structure, and X-ray properties identify it as a blazar with a jet aligned toward Earth. Blazars are rare and account for only a small fraction of all quasars. The discovery of J0410−0139 implies the existence of a much larger population of similar jetted sources in the early universe. These jets likely enhance black hole growth and significantly affect their host galaxies.

Observations with instruments such as the U.S. National Science Foundation Very Large Array (NSF VLA), the NSF Very Long Baseline Array (NSF VLBA), the Chandra X-ray Observatory, and the Atacama Large Millimeter/submillimeter Array (ALMA) indicate that J0410−0139 exhibits radio emission amplified by relativistic beaming, a hallmark of blazars. Its spectrum also confirms stable accretion and emission regions typical of active black holes. This discovery raises questions about how supermassive black holes grow so rapidly in the universe’s infancy. Models may need to account for jet-enhanced accretion or obscured, super-Eddington growth to reconcile this finding with the known black hole population at such high redshifts.

“This blazar offers a unique laboratory to study the interplay between jets, black holes, and their environments during one of the universe’s most transformative epochs,” said Dr. Emmanuel Momjian of the NSF National Radio Astronomy Observatory, a co-lead of the study, “The alignment of J0410−0139’s jet with our line of sight allows astronomers to peer directly into the heart of this cosmic powerhouse.”

The existence of J0410−0139 at such an early time suggests that current radio surveys might uncover additional jetted quasars from the same era. Understanding these objects will illuminate the role of jets in shaping galaxies and growing supermassive black holes in the early universe.




About NRAO

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

For media inquiries or further information, please contact:

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Sunday, December 22, 2024

NASA Missions Spot Cosmic 'Wreath' Displaying Stellar Circle of Life

NGC 602
Credit: X-ray: NASA/CXC; Infrared: ESA/Webb, NASA & CSA, P. Zeilder, E.Sabbi, A. Nota, M. Zamani; Image Processing: NASA/CXC/SAO/L. Frattare and K. Arcand





Since antiquity, wreaths have symbolized the cycle of life, death, and rebirth. It is fitting then that one of the best places for astronomers to learn more about the stellar lifecycle resembles a giant holiday wreath itself.

The star cluster NGC 602 lies on the outskirts of the Small Magellanic Cloud, which is one of the closest galaxies to the Milky Way, about 200,000 light-years from Earth. The stars in NGC 602 have fewer heavier elements compared to the Sun and most of the rest of the galaxy. Instead, the conditions within NGC 602 mimic those for stars found billions of years ago when the universe was much younger.

This new image combines data from NASA’s Chandra X-ray Observatory with a previously released image from the agency’s James Webb Space Telescope. The dark ring-like outline of the wreath seen in Webb data (represented as orange, yellow, green, and blue) is made up of dense clouds of filled dust.

Meanwhile, X-rays from Chandra (red) show young, massive stars that are illuminating the wreath, sending high-energy light into interstellar space. These X-rays are powered by winds flowing from the young, massive stars that are sprinkled throughout the cluster. The extended cloud in the Chandra data likely comes from the overlapping X-ray glow of thousands of young, low-mass stars in the cluster.

NGC 2264, the “Christmas Tree Cluster”
Credit: X-ray: NASA/CXC/SAO; Optical: Clow, M.; Image Processing: NASA/CXC/SAO/L. Frattare and K. Arcand);

View Animated Version

In addition to this cosmic wreath, a new version of the “Christmas tree cluster” is also now available. Like NGC 602, NGC 2264 is a cluster of young stars between one and five million years old. (For comparison, the Sun is a middle-aged star about 5 billion years old — about 1,000 times older.) In this image of NGC 2264, which is much closer than NGC 602 at a distance of about 2,500 light-years from Earth, Chandra data (red, purple, blue, and white) has been combined with optical data (green and violet) captured from by astrophotographer Michael Clow from his telescope in Arizona in November 2024.

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

Quick Look: NASA Missions Spot Cosmic 'Wreath' Displaying Stellar Circle of Life




Visual Description:

This release includes two composite images, each featuring a star cluster that strongly resembles holiday greenery.

The first image depicts star cluster NGC 602 in vibrant and festive colors. The cluster includes a giant dust cloud ring, shown in greens, yellows, blues, and oranges. The green hues and feathery edges of the ring cloud create the appearance of a wreath made of evergreen boughs. Hints of red representing X-rays provide shading, highlighting layers within the wreath-like ring cloud.

The image is aglow with specks and dots of colorful, festive light, in blues, golds, whites, oranges, and reds. These lights represent stars within the cluster. Some of the lights gleam with diffraction spikes, while others emit a warm, diffuse glow. Upon closer inspection, many of the glowing specks have spiraling arms, indicating that they are, in fact, distant galaxies.

The second image in today's release is a new depiction of NGC 2264, known as the "Christmas Tree Cluster". Here, wispy green clouds in a conical shape strongly resemble an evergreen tree. Tiny specks of white, blue, purple, and red light, stars within the cluster, dot the structure, turning the cloud into a festive, cosmic Christmas tree!




Fast Facts for NGC 602:

Credit: X-ray: NASA/CXC; Infrared: ESA/Webb, NASA & CSA, P. Zeilder, E.Sabbi, A. Nota, M. Zamani; Image Processing: NASA/CXC/SAO/L. Frattare and K. Arcand
Scale: Image is about 3 arcmin (175 light-years) across.
Category: Normal Stars & Star Clusters
Coordinates (J2000): RA 01h 29m 28.7s | Dec -73° 33´ 40.8"
Constellation: Hydrus
Observation Dates: 11 pointings between 31 March and 29 April, 2010
Observation Time: 80 hours 45 minutes (3 days 8 hours 45 minutes)
Obs. ID: 10985-10986, 11978-11979, 11988-11989, 12130-12131, 12134, 12136, 12207
Instrument: ACIS
References: Oskinova, L. et al, 2013, ApJ, 765 73; arXiv:1301.3500
Color Code: X-ray: red; Infrared: orange, yellow, green, and blue
Distance Estimate: About 200,000 light-years



Fast Facts for NGC 2264:

Credit: X-ray: NASA/CXC/SAO; Optical: Clow, M.; Image Processing: NASA/CXC/SAO/L. Frattare and K. Arcand
Scale: Image is about 77 arcmin (56 light-years) across.
Category: Normal Stars & Star Clusters
Coordinates (J2000): RA: 06h 40m 42.8s | Dec: +09° 49' 3.6"
Constellation: Monoceros
Observation Dates: 8 observations from February 2002 to December 2011
Observation Time: 137 hours 26 minutes ( 5 days 17 hours 26 mintues)
Obs. IDs: 2540, 2550, 9768, 9769, 13610, 13611, 14368, 14369
Instrument: ACIS
References: Ramirez, S.V., et al., 2004, AJ, 127,2659; arXiv:astro-ph:0401533
Color Code: X-ray: red, green, and blue; Optical: green and white
Distance Estimate: About 2,500 light-years


Saturday, December 21, 2024

M87's Powerful Jet Unleashes Rare Gamma-ray Outburst

Fig. 1: Light curve of the gamma-ray flare (bottom) and collection of quasi-simultaneously observed images of the M87 jet (top) at various scales obtained in radio and X-ray during the 2018 campaign. The telescopes, the wavelength observation range and scale are shown at the top right of each image. © EHT Collaboration, Fermi-LAT Collaboration, H.E.S.S. Collaboration, MAGIC Collaboration, VERITAS Collaboration, EAVN Collaboratio

Multi-wavelength Campaign with Effelsberg and mm-VLBI Arrays Reveals a High-energy Gamma-ray Flare

The shadow of the black hole in Messier 87 has been imaged by with global radio array telescopes over the last years. Joint campaigns have been coordinated annually ever since. An international team of researchers has just released the results of a large campaign on M87 of Event Horizon Telescope and Global mm-VLBI Array observations in 2018, involving over twenty-five ground-based and space-based telescopes. The team, including a number of researchers from the Max Planck Institute for Radio Astronomy in Bonn, Germany, report a spectacular flare at multiple wavelengths from the powerful relativistic jet emanating from the very centre of the same galaxy. This study reveals the first observation in over a decade of a high-energy gamma-ray flare. Photons up to thousands of billions of times the energy of visible light from the supermassive black hole M87* were detected after obtaining nearly simultaneous spectra of that galaxy with the broadest wavelength coverage ever collected.

Millimetre VLBI facilities, represented by two arrays, the Event Horizon Telescope (EHT) and the Global mm-VLBI Array (GMVA), the latter coordinated by the Max Planck Institute for Radio Astronomy (MPIfR), are global networks of radio telescopes regularly interconnected to observe the innermost structures of galactic nuclei and to image the shadows of supermassive black holes.

“We were fortunate to detect a gamma-ray flare from M87 during the EHT's multi-wavelength campaign—the first such event in over a decade,” says Giacomo Principe, publication coordinator and researcher at the University of Trieste. “This rare event allowed us to pinpoint the region producing the gamma-ray emission. Recent and upcoming observations with a more sensitive EHT array will provide critical insights into the physics around M87’s supermassive black hole, exploring the disk-jet connection and the origins of gamma-ray photons.”

Messier 87, also known as Virgo A or NGC 4486, is the brightest object in the Virgo cluster of galaxies, the largest gravitationally bound type of structure in the universe. The relativistic jet examined by the researchers is surprising in its extent, reaching sizes that exceed the black hole’s event horizon by tens of millions of times (7 orders of magnitude) - akin to the difference between the size of a bacterium and the largest known blue whale.

The energetic flare, which lasted approximately three days and suggests an emission region of less than three light-days in size (~170 AU, where 1 Astronomical Unit is the distance from the Sun to Earth), revealed a bright burst of high-energy emission—well above the energies typically detected by radio telescopes from the black hole region.

“High-cadence very-high-energy gamma-ray observations during both a steady state and a rare short-term flare—the first in over a decade—were achieved through the collaboration of three imaging high-energy telescope arrays”, explains Alexander Hahn from the Max Planck Institute for Physics, a co-author of the study. “Combined with simultaneous multi-wavelength data at lower energies, these observations offer crucial insights into the extreme processes powering these cosmic events.”

During the campaign, the LAT instrument aboard the Fermi space observatory detected an increase in high-energy gamma-ray flux with energies up to billions of times greater than visible light. The satellites Chandra and NuSTAR then collected high-quality data in the X-ray band. Radio observations with VLBI arrays such as the GMVA, the Very Long Baseline Array (VLBA) and the East Asian VLBI Network (EAVN) show a relativistic jet and an apparent annual change in the jet's position angle within a few milliarcseconds of arc from the galaxy's core.

“The radio imaging provides a unique perspective, allowing astronomers to track the structural and temporal evolution of the jet at unprecedented angular resolutions”, says Thomas Krichbaum of the MPIfR. “In this campaign, radio data not only constrained the jet geometry but also served as a vital reference for correlating the gamma-ray emission with the relativistic jet dynamics.”

Observations show changes in the position of the ring's asymmetry (the black hole's event horizon) and the jet's position. This suggests a physical link between these structures on very different scales. “The first image from the 2017 observational campaign showed that the ring’s emission was uneven, with brighter areas indicating asymmetries. Subsequent 2018 observations confirmed these findings, showing that the position angle of the asymmetry had shifted”, says Daryl Haggard, professor at McGill University and co-coordinator of the EHT multi-wavelength working group.

This is a prime example of how radio observations of the most violent objects in the Universe are complemented by high-energy telescopes like those used in this major campaign. The MPIfR participates in this effort with observations performed with the GMVA and the EHT. These radio data were, among other, postprocessed at the MPIfR correlator facility in Bonn. MPIfR radio telescopes participating in these arrays are the 100-m telescope in Effelsberg and the 12-m APEX telescope in Chile. The 30-m IRAM telescope in Pico Veleta, Spain, recently complemented by the IRAM/NOEMA telescope array in the French Alps, added substantial sensitivity to these observations.

“This observing campaign produced the first image ever showing both the black hole shadow and the jet in M87, presented in April 2023, and now we see that new, exciting results are coming from the coordinated observations carried out around the second global EHT campaign”, recalls Eduardo Ros, astronomer at the MPIfR and European scheduler of the GMVA.

J. Anton Zensus, director at the MPIfR and founding chair of the EHT collaboration, concludes: "The contribution of cutting-edge technology in radio astronomy, in coordination with different facilities on Earth and beyond, shows here in a special way how multi-band studies of sources such as Messier 87 pave the way for stimulating future research and potential breakthroughs in understanding the Universe"

Fig. 2: The observatories and telescopes that participated in the 2018 multiband campaign to detect the high-energy gamma-ray flare from the M87* black hole. © EHT Collaboration, Fermi-LAT Collaboration, H.E.S.S. Collaboration, MAGIC Collaboration, VERITAS Collaboration, EAVN Collaboration.




Additional Information

The EHT collaboration involves more than 400 researchers from Africa, Asia, Europe, North and South America, with around 270 participating in this paper. The international collaboration aims to capture the most detailed images of black holes using a virtual Earth-sized telescope. Supported by considerable international efforts, the EHT links existing telescopes using novel techniques to create a fundamentally new instrument with the highest angular resolving power that has yet been achieved.

The EHT consortium consists of 13 stakeholder institutes; the Academia Sinica Institute of‬ Astronomy and Astrophysics, the University of Arizona, the Center for Astrophysics | Harvard &‬ Smithsonian, the University of Chicago, the East Asian Observatory, the Goethe University‬ Frankfurt, the Institut de Radioastronomie Millimétrique, the Large Millimeter Telescope, the Max Planck‬ Institute for Radio Astronomy, the MIT Haystack Observatory, the National Astronomical Observatory of‬ Japan, the Perimeter Institute for Theoretical Physics, and the Radboud University.‬‬

The EHT array operating at 1.3 mm wavelength included ALMA, APEX, the IRAM 30-meter Telescope, the IRAM NOEMA Observatory, the James Clerk Maxwell Telescope (JCMT), the Large Millimeter Telescope (LMT), the Submillimeter Array (SMA), the Submillimeter Telescope (SMT), the South Pole Telescope (SPT), the Kitt Peak Telescope (KP), and the Greenland Telescope (GLT). The GMVA, observing at adjacent days at a wavelength of 3.5 mm included the 100-m radio telescope in Effelsberg. GMVA and EHT data were post-processed at the MPIfR correlator facility. The EHT data were also correlated at the MIT/Haystack Observatory in Westford, MA, USA. Further analysis was performed in the framework of the global EHT collaboration.

The second EHT and multi-wavelength campaign in 2018 leveraged more than two dozen high-profile observational facilities, including NASA’s Fermi-LAT, the Hubble Space Telescope, NuSTAR, Chandra, and Swift telescopes, together with the world’s three largest Imaging Atmospheric Cherenkov Telescope arrays (H.E.S.S., MAGIC and VERITAS). These observatories are sensitive to X-ray photons as well as high-energy and very-high-energy gamma-rays, respectively.

Researchers affiliated with the Max Planck Institut für Radioastronomie, listed as co-authors in the published research, are: Jae-Young Kim, Ru-sen Lu, and also Walter Alef, Rebecca Azulay, Uwe Bach, Anne-Kathrin Baczko, Silke Britzen, Gregory Desvignes, Sergio A. Dzib, Ralph Eatough, Christian M. Fromm, Michael Janssen, Joana A. Kramer, Michael Kramer, Thomas P. Krichbaum, Mikhail Lisakov, Jun Liu, Kuo Liu, Andrei P. Lobanov, Nicholas R. MacDonald, Nicola Marchili, Karl M. Menten, Cornelia Müller, Hendrik Müller, Gisela Ortiz-Leon, Georgios Filippos Paraschos, Felix Poetzl, Eduardo Ros, Helge Rottmann, Alan L. Roy, Tuomas Savolainen, Lijing Shao, Pablo Torne, Efthalia Traianou, Jan Wagner, Robert Wharton, Maciek Wielgus, Gunther Witzel, J. Anton Zensus, and Guang-Yao Zhao.



Contact:

Dr. Thomas Krichbaum
tel:+49 228 525-295

tkrichbaum@mpifr-bonn.mpg.de
Max Planck Institute for Radio Astronomy, Bonn

Prof. Dr. J. Anton Zensus
Director and Head of Research Division Radi Astronomy / VLBI
tel:+49 228 525-298

azensus@mpifr-bonn.mpg.de
Max Planck Institute for Radio Astronomy, Bonn

Prof. Dr. Eduardo Ros
tel:+49 228 525-125

ros@mpifr-bonn.mpg.de
Max-Planck-Institut für Radioastronomie, Bonn

Dr. Norbert Junkes
Press and Public Outreach
tel:+49 228 525-399

njunkes@mpifr-bonn.mpg.de Max Planck Institute for Radio Astronomy, Bonn



Original Paper

Broadband Multi-wavelength Properties of M87 during the 2018 EHT Campaign including a Very High Energy Flaring Episode
The Event Horizon Telescope- Multi-wavelength science working group, The Event Horizon Telescope Collaboration, The Fermi Large Area Telescope Collaboration, H.E.S.S. Collaboration, MAGIC Collaboration, VERITAS Collaboration, and EAVN Collaboration. In: A&A, 692, A140 (2024). DOI: 10.1051/0004-6361/202450497 .

The Event Horizon Telescope- Multi-wavelength science working group, The Event Horizon Telescope Collaboration, The Fermi Large Area Telescope Collaboration, H.E.S.S. Collaboration, MAGIC Collaboration, VERITAS Collaboration, and EAVN Collaboration (arXiv preprint).

Animation

Gamma-ray Flare
Very high energy gamma-ray flare observed by Cherenkov telescopes (H.E.S.S., MAGIC and VERITAS). Credits: EHT Collaboration, Fermi-LAT Collaboration, H.E.S.S. Collaboration, MAGIC Collaboration, VERITAS Collaboration, EAVN Collaboration).



Links

Radio Astronomy / VLBI
Research Department at MPIfR

Fundamental Physics in Radio Astronomy
Research Department at MPIfR

Millimeter and Submillimeter Astronomy
Research Department at MPIfR

Radio Telescope Effelsberg
Effelsberg 100-m Radio Telescope

EHT
Event Horizon Telescope (EHT)

GMVA
Global mm-VLBI Array (GMVA)

VLBA
Very Long Baseline Array (VLBA)

EAVN
East-Asian VLBI Network (EAVN)

Fermi LAT
The Fermi Large Area Telescope (LAT)

H.E.S.S.
The H.E.S.S. Collaboration

MAGIC
The MAGIC Telescopes

VERITAS
VERITAS (Very Energetic Radiation Imaging Telescope Array System)



Parallel Press Releases

CfA Astronomers Help Catch Rare Gamma-Ray Outburst from M87’s Powerful Jet
Harvard/CfA Press Release, December 13, 2024

Event Horizon Telescope: rare gamma-ray burst observed from M87, UniTS also involved
UniTS Press Release, December 13, 2024

The Event Horizon Telescope Collaboration Reports a Spectacular Flare from the Centre of the Messier 87 Galaxy
CITA Press Release, December 13, 2024

M87's powerful jet unleashes rare gamma-ray outburst
Press Release Nagoya City University/Eurekalert, December 13, 2024

Brillamento di luce gamma nel getto di M87
INAF Press Release, December 13, 2024

L’INATTESO BRILLAMENTO NEL GETTO DI M87 OSSERVATO DALLE ONDE RADIO AI RAGGI GAMMA
INFN Press Release, December 13, 2024

【プレスリリース】M87のジェットから強力なガンマ線フレアを検出〜EHTと多波長観測が捉えた巨大ブラックホールの活動期〜
Press Release ICRR/Univ. Tokyo, December 13, 2024

M87 のジェットから強力なガンマ線フレアを検出 〜EHT と多波長観測が捉えた巨大ブラックホールの活動期〜
Kogakuin University Press Release, December 13, 2024


Friday, December 20, 2024

NASA's Webb Finds Planet-Forming Disks Lived Longer in Early Universe

Protoplanetary Disks in NGC 346 (NIRCam Image)
Credits/Image: NASA, ESA, CSA, STScI, Olivia C. Jones (UK ATC), Guido De Marchi (ESTEC), Margaret Meixner (USRA)

Protoplanetary Disks in NGC 346 Spectra (NIRSpec)
Credits/Illustration: NASA, ESA, CSA, Joseph Olmsted (STScI)

Credits/Image: NASA, ESA, CSA, STScI, Olivia C. Jones (UK ATC), Guido De Marchi (ESTEC), Margaret Meixner (USRA), Antonella Nota (ESA)



NASA’s James Webb Space Telescope just solved a conundrum by proving a controversial finding made with the agency’s Hubble Space Telescope more than 20 years ago.

In 2003, Hubble provided evidence of a massive planet around a very old star, almost as old as the universe. Such stars possess only small amounts of heavier elements that are the building blocks of planets. This implied that some planet formation happened when our universe was very young, and those planets had time to form and grow big inside their primordial disks, even bigger than Jupiter. But how? This was puzzling.

To answer this question, researchers used Webb to study stars in a nearby galaxy that, much like the early universe, lacks large amounts of heavy elements. They found that not only do some stars there have planet-forming disks, but that those disks are longer-lived than those seen around young stars in our Milky Way galaxy.

“With Webb, we have a really strong confirmation of what we saw with Hubble, and we must rethink how we model planet formation and early evolution in the young universe,” said study leader Guido De Marchi of the European Space Research and Technology Centre in Noordwijk, Netherlands.

A Different Environment in Early Times

In the early universe, stars formed from mostly hydrogen and helium, and very few heavier elements such as carbon and iron, which came later through supernova explosions.

“Current models predict that with so few heavier elements, the disks around stars have a short lifetime, so short in fact that planets cannot grow big,” said the Webb study’s co-investigator Elena Sabbi, chief scientist for Gemini Observatory at the National Science Foundation’s NOIRLab in Tucson. "But Hubble did see those planets, so what if the models were not correct and disks could live longer?"

To test this idea, scientists trained Webb on the Small Magellanic Cloud, a dwarf galaxy that is one of the Milky Way’s nearest neighbors. In particular, they examined the massive, star-forming cluster NGC 346, which also has a relative lack of heavier elements. The cluster served as a nearby proxy for studying stellar environments with similar conditions in the early, distant universe.

Hubble observations of NGC 346 from the mid 2000s revealed many stars about 20 to 30 million years old that seemed to still have planet-forming disks around them. This went against the conventional belief that such disks would dissipate after 2 or 3 million years.

“The Hubble findings were controversial, going against not only empirical evidence in our galaxy but also against the current models,” said De Marchi. “This was intriguing, but without a way to obtain spectra of those stars, we could not really establish whether we were witnessing genuine accretion and the presence of disks, or just some artificial effects.”

Now, thanks to Webb’s sensitivity and resolution, scientists have the first-ever spectra of forming, Sun-like stars and their immediate environments in a nearby galaxy.

“We see that these stars are indeed surrounded by disks and are still in the process of gobbling material, even at the relatively old age of 20 or 30 million years,” said De Marchi. “This also implies that planets have more time to form and grow around these stars than in nearby star-forming regions in our own galaxy.”

A New Way of Thinking

This finding refutes previous theoretical predictions that when there are very few heavier elements in the gas around the disk, the star would very quickly blow away the disk. So the disk’s life would be very short, even less than a million years. But if a disk doesn't stay around the star long enough for the dust grains to stick together and pebbles to form and become the core of a planet, how can planets form?

The researchers explained that there could be two distinct mechanisms, or even a combination, for planet-forming disks to persist in environments scarce in heavier elements.

First, to be able to blow away the disk, the star applies radiation pressure. For this pressure to be effective, elements heavier than hydrogen and helium would have to reside in the gas. But the massive star cluster NGC 346 only has about ten percent of the heavier elements that are present in the chemical composition of our Sun. Perhaps it simply takes longer for a star in this cluster to disperse its disk.

The second possibility is that, for a Sun-like star to form when there are few heavier elements, it would have to start from a larger cloud of gas. A bigger gas cloud will produce a bigger disk. So there is more mass in the disk and therefore it would take longer to blow the disk away, even if the radiation pressure were working in the same way.

“With more matter around the stars, the accretion lasts for a longer time,” said Sabbi. "The disks take ten times longer to disappear. This has implications for how you form a planet, and the type of system architecture that you can have in these different environments. This is so exciting.”

The science team’s paper appears in the Dec. 16 issue of The Astrophysical Journal.

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).

The Hubble Space Telescope has been operating for over three decades and continues to make ground-breaking discoveries that shape our fundamental understanding of the universe. Hubble is a project of international cooperation between NASA and ESA (European Space Agency). NASA's Goddard Space Flight Center in Greenbelt manages the telescope and mission operations. Lockheed Martin Space, based in Denver also supports mission operations at Goddard. The Space Telescope Science Institute in Baltimore, which is operated by the Association of Universities for Research in Astronomy, conducts Hubble science operations for NASA.




About This Release

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Media Contact:

Ann Jenkins
Space Telescope Science Institute, Baltimore, Maryland

Christine Pulliam
Space Telescope Science Institute, Baltimore, Maryland

Permissions: Content Use Policy

Contact Us: Direct inquiries to the News Team.

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Thursday, December 19, 2024

First ever binary star found near our galaxy’s supermassive black hole

PR Image eso2418a
Location of binary star D9 in the Milky Way

PR Image eso2418b
Image of the binary star D9 close to Sagittarius A* (annotated)

PR Image eso2418c
Image of the binary star D9 close to Sagittarius A*

PR Image eso2418d
A 340-million pixel starscape from Paranal

PR Image eso2418e
Straight to the Milky Way's heart

PR Image eso2418f
Sagittarius A* in the constellation of Sagittarius



Videos

First ever binary star found near Sgr A* | ESO News
PR Video eso2418a
First ever binary star found near Sgr A* | ESO News

Star pair D9 orbiting the supermassive black hole Sgr A* (artist's animation)
PR Video eso2418b
Star pair D9 orbiting the supermassive black hole Sgr A* (artist's animation)

Artist's animation of star pair D9 orbiting the supermassive black hole Sgr A*
PR Video eso2418c
Artist's animation of star pair D9 orbiting the supermassive black hole Sgr A*



An international team of researchers has detected a binary star orbiting close to Sagittarius A*, the supermassive black hole at the centre of our galaxy. It is the first time a stellar pair has been found in the vicinity of a supermassive black hole. The discovery, based on data collected by the European Southern Observatory’s Very Large Telescope (ESO’s VLT), helps us understand how stars survive in environments with extreme gravity, and could pave the way for the detection of planets close to Sagittarius A*.

Black holes are not as destructive as we thought,” says Florian Peißker, a researcher at the University of Cologne, Germany, and lead author of the study published today in Nature Communications. Binary stars, pairs of stars orbiting each other, are very common in the Universe, but they had never before been found near a supermassive black hole, where the intense gravity can make stellar systems unstable.

This new discovery shows that some binaries can briefly thrive, even under destructive conditions. D9, as the newly discovered binary star is called, was detected just in time: it is estimated to be only 2.7 million years old, and the strong gravitational force of the nearby black hole will probably cause it to merge into a single star within just one million years, a very narrow timespan for such a young system.

This provides only a brief window on cosmic timescales to observe such a binary system — and we succeeded!” explains co-author Emma Bordier, a researcher also at the University of Cologne and a former student at ESO.

For many years, scientists also thought that the extreme environment near a supermassive black hole prevented new stars from forming there. Several young stars found in close proximity to Sagittarius A* have disproved this assumption. The discovery of the young binary star now shows that even stellar pairs have the potential to form in these harsh conditions. “The D9 system shows clear signs of the presence of gas and dust around the stars, which suggests that it could be a very young stellar system that must have formed in the vicinity of the supermassive black hole,” explains co-author Michal Zajaček, a researcher at Masaryk University, Czechia, and the University of Cologne.

The newly discovered binary was found in a dense cluster of stars and other objects orbiting Sagittarius A*, called the S cluster. Most enigmatic in this cluster are the G objects, which behave like stars but look like clouds of gas and dust.

It was during their observations of these mysterious objects that the team found a surprising pattern in D9. The data obtained with the VLT’s ERIS instrument, combined with archival data from the SINFONI instrument, revealed recurring variations in the velocity of the star, indicating D9 was actually two stars orbiting each other. “I thought that my analysis was wrong,” Peißker says, “but the spectroscopic pattern covered about 15 years, and it was clear this detection is indeed the first binary observed in the S cluster.”

The results shed new light on what the mysterious G objects could be. The team proposes that they might actually be a combination of binary stars that have not yet merged and the leftover material from already merged stars.

The precise nature of many of the objects orbiting Sagittarius A*, as well as how they could have formed so close to the supermassive black hole, remain a mystery. But soon, the GRAVITY+ upgrade to the VLT Interferometer and the METIS instrument on ESO’s Extremely Large Telescope (ELT), under construction in Chile, could change this. Both facilities will allow the team to carry out even more detailed observations of the Galactic centre, revealing the nature of known objects and undoubtedly uncovering more binary stars and young systems. “Our discovery lets us speculate about the presence of planets, since these are often formed around young stars. It seems plausible that the detection of planets in the Galactic centre is just a matter of time,” concludes Peißker.

Source: ESO/News



More information

This research was presented in the paper “A binary system in the S cluster close to the supermassive black hole Sagittarius A*” published today in Nature Communications (doi: 10.1038/s41467-024-54748-3).

The team is composed of F. Peißker (Institute of Physics I, University of Cologne, Germany [University of Cologne]), M. Zajaček (Department of Theoretical Physics and Astrophysics, Masaryk University, Brno, Czechia; University of Cologne), L. Labadie (University of Cologne), E. Bordier (University of Cologne), A. Eckart (University of Cologne; Max Planck Institute for Radio Astronomy, Bonn, Germany), M. Melamed (University of Cologne), and V. Karas (Astronomical Institute, Czech Academy of Sciences, Prague, Czechia).

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 Cherenkov Telescope Array South, 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

Florian Peißker
Institute of Physics 1, University of Cologne
Cologne, Germany
Tel: +49 221 470 7791
Email:
peissker@ph1.uni-koeln.de

Emma Bordier
Institute of Physics 1, University of Cologne
Cologne, Germany
Tel: +49 221 470 3548
Email:
bordier@ph1.uni-koeln.de

Michal Zajaček
Department of Theoretical Physics and Astrophysics, Masaryk University
Brno, Czechia
Tel: +420 549 49 8773
Email:
zajacek@physics.muni.cz

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, December 18, 2024

Seeing eye to eye

An oval-shaped spiral galaxy. Its core is a compact, glowing blue spot. A bright bar of light, lined with dark reddish dust, extends horizontally to the edge of the disc. A spiral arm emerges from each end of the bar and follows the edge of the disc, lined with blue and red glowing patches of stars, to the opposite end and a little off the galaxy. Blue stars are scattered between us and the galaxy. Credit: ESA/Hubble & NASA, D. Thilker

Featured in this NASA/ESA Hubble Space Telescope Picture of the Week is the spiral galaxy NGC 2566, which sits 76 million light-years away in the constellation Puppis. A prominent bar of stars stretches across the centre of this galaxy, and spiral arms emerge from each end of the bar. Because NGC 2566 appears tilted from our perspective, its disc takes on an almond shape, giving the galaxy the appearance of a cosmic eye.

As NGC 2566 gazes at us, astronomers gaze right back, using Hubble to survey the galaxy’s star clusters and star-forming regions. The Hubble data are especially valuable for studying stars that are just a few million years old; these stars are bright at the ultraviolet and visible wavelengths to which Hubble is sensitive. Using these data, researchers will measure the ages of NGC 2566’s stars, helping to piece together the timeline of the galaxy’s star formation and the exchange of gas between star-forming clouds and stars themselves.

Several other astronomical observatories have examined NGC 2566, including the NASA/ESA/CSA James Webb Space Telescope. The Webb data complement this Hubble image, adding a view of NGC 2566’s warm, glowing dust to Hubble’s stellar portrait. At the long-wavelength end of the electromagnetic spectrum, NGC 2566 has also been observed by the Atacama Large Millimeter/submillimeter Array (ALMA). ALMA is a network of 66 radio telescopes that work together as one to capture detailed images of the clouds of gas in which stars form. Together, Hubble, Webb and ALMA provide an overview of the formation, lives and deaths of stars in galaxies across the Universe.

Source: ESA/potw


Tuesday, December 17, 2024

Dusty Crescents Around a Baby Star

The MWC 758 protoplanetary disk, as seen by the Very Large Telescope (yellow areas) and the Atacama Large Millimeter/submillimeter Array (blue areas). Credit: ESO/A. Garufi et al.; R. Dong et al.; ALMA (ESO/NAOJ/NRAO); CC BY 4.0


Complicated Disks

Did vortices sculpt the crescent-shaped clumps of dust around the young star MWC 758? Using data from the Atacama Large Millimeter/submillimeter Array (ALMA), researchers have mapped the motions of the dust clumps and weighed in on the vortex hypothesis.

How planets form is one of the most pressing questions in astronomy. Observations increasingly show that protoplanetary disks, the sites of planet formation, are complex objects. These disks feature rings, gaps, spirals, and vortices, any of which might signal the presence of baby planets.

Among the intriguing features seen in protoplanetary disks are crescents: asymmetric regions where the density of dust is enhanced. These regions are readily visible in observations by ALMA and have been found in several protoplanetary disks.

Researchers suspect that crescents are caused by swirling regions called vortices. Like debris caught in an eddy in a stream, dust could theoretically become trapped in a vortex, forming the clumps seen in images — and potentially creating a perfect dusty ecosystem for planets to form.

Images of the MWC 758 disk taken at a wavelength of 1.3 mm in 2017 (left) and 2021 (right).
Credit: Kuo et al. 2024

The Causes of Crescents

Recently, a team led by I-Hsuan Genevieve Kuo (Academia Sinica Institute of Astronomy and Astrophysics, Taiwan; University of Arizona) investigated the causes of crescents in the protoplanetary disk around the star MWC 758, also called HD 36112. MWC 758 is a 1.5–2-solar-mass star that is about 3.5 million years old and less than 500 light-years away. Its disk sports several intriguing features, including two crescents and a spiral. Previous research has attributed these features to the presence of one or more planets.

Vortex theory predicts that vortices in a protoplanetary disk will revolve around the central star at the Keplerian velocity (i.e., following the predictions of Kepler’s laws of motion). To test this theory, Kuo’s team used ALMA data from 2017 and 2021 to measure the motion of the two crescents. They found that the crescents moved in the direction of the disk’s rotation, with the inner crescent moving 50% slower than expected for the vortex hypothesis and the outer crescent moving 33% faster than expected.

Observed azimuthal (i.e., around the disk) velocity of the dust clumps (green and dark blue triangles) and expected velocity for Keplerian rotation (aqua circles).Credit: Kuo et al. 2024

Spiral vs. Vortex

Does this finding necessarily rule out the vortex hypothesis? Kuo and coauthors first investigated and eliminated the possibility that imperfections in the disk, like warps or eccentricity, were the cause of the mismatch with theory. They then noted that the motion of the crescents matches the Keplerian velocity at a radius of about 0.46 arcsecond. If a planet were present at that radius, there’s a chance it could throw the system off-kilter and produce the observed behavior — but MWC 758’s putative planets are located well inside and outside this radius.

Instead, the non-Keplerian rotation of the dust clumps might be caused by the interaction of vortices and spirals. In this case, the vortices themselves, which are invisible to us, are moving in the way predicted by theory, but the spiral knocks the (visible) dust off course.

Luckily, this prediction is testable. If vortices and spirals are vying for control of the dust crescents in MWC 758’s disk, their power struggle would be less effective on large dust grains than on small dust grains. In other words, large dust grains should adhere more closely to the expected Keplerian velocity than small dust grains do. Future high-resolution observations at different wavelengths, which probe grains of different sizes, may provide an answer.

By Kerry Hensley

Citation

“ALMA Observations of Proper Motions of the Dust Clumps in the Protoplanetary Disk MWC 758,” I-Hsuan Genevieve Kuo et al 2024 ApJL 975 L33. doi:10.3847/2041-8213/ad86c1



Monday, December 16, 2024

NASA's Chandra Sees Black Hole Jet Stumble Into Something in the Dark

Centaurus A
Credit: NASA/CXC/SAO/D. Bogensberger et al.; Image Processing: NASA/CXC/SAO/N. Wolk





Even matter ejected by black holes can run into objects in the dark. Using NASA’s Chandra X-ray Observatory, astronomers have found an unusual mark from a giant black hole’s powerful jet striking an unidentified object in its path.

The discovery was made in a galaxy called Centaurus A (Cen A), located about 12 million light-years from Earth. Astronomers have long studied Cen A because it has a supermassive black hole in its center sending out spectacular jets that stretch out across the entire galaxy. The black hole launches this jet of high-energy particles not from inside the black hole, but from intense gravitational and magnetic fields around it.

The image shows low-energy X-rays seen by Chandra represented in pink, medium-energy X-rays in purple, and the highest-energy X-rays in blue.
In this latest study, researchers determined that the jet is — at least in certain spots — moving at close to the speed of light. Using the deepest X-ray image ever made of Cen A, they also found a patch of V-shaped emission connected to a bright source of X-rays, something that had not been seen before in this galaxy.

Called C4, this source is located close to the path of the jet from the supermassive black hole and is highlighted in the inset. The arms of the “V” are at least about 700 light-years long. For context, the nearest star to Earth is about 4 light-years away.

Source C4 in the Centaurus A Galaxy
Credit: NASA/CXC/SAO/D. Bogensberger et al.; Image Processing: NASA/CXC/SAO/N. Wolk)

While the researchers have ideas about what is happening, the identity of the object being blasted is a mystery because it is too distant for its details to be seen, even in images from the current most powerful telescopes.

The incognito object being rammed may be a massive star, either by itself or with a companion star. The X-rays from C4 could be caused by the collision between the particles in the jet and the gas in a wind blowing away from the star. This collision can generate turbulence, causing a rise in the density of the gas in the jet. This, in turn, ignites the X-ray emission seen with Chandra.

The shape of the “V,” however, is not completely understood. The stream of X-rays trailing behind the source in the bottom arm of the “V” is roughly parallel to the jet, matching the picture of turbulence causing enhanced X-ray emission behind an obstacle in the path of the jet. The other arm of the “V” is harder to explain because it has a large angle to the jet, and astronomers are unsure what could explain that.

This is not the first time astronomers have seen a black hole jet running into other objects in Cen A. There are several other examples where a jet appears to be striking objects — possibly massive stars or gas clouds. However, C4 stands out from these by having the V-shape in X-rays, while other obstacles in the jet’s path produce elliptical blobs in the X-ray image. Chandra is the only X-ray observatory capable of seeing this feature. Astronomers are trying to determine why C4 has this different post-contact appearance, but it could be related to the type of object that the jet is striking or how directly the jet is striking it.

A paper describing these results appears in a recent issue of The Astrophysical Journal. The authors of the study are David Bogensberger (University of Michigan), Jon M. Miller (University of Michigan), Richard Mushotsky (University of Maryland), Niel Brandt (Penn State University), Elias Kammoun (University of Toulouse, France), Abderahmen Zogbhi (University of Maryland), and Ehud Behar (Israel Institute of Technology).

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





Visual Description:

This release features a series of images focusing on a collision between a jet of matter blasting out of a distant black hole, and a mysterious, incognito object.

At the center of the primary image is a bright white dot, encircled by a hazy purple blue ring tinged with neon blue. This is the black hole at the heart of the galaxy called Centaurus A. Shooting out of the black hole is a stream of ejected matter. This stream, or jet, shoots in two opposite directions. It shoots toward us, widening as it reaches our upper left, and away from us, growing thinner and more faint as it recedes toward the lower right. In the primary image, the jet resembles a trail of hot pink smoke. Other pockets of granular, hot pink gas can be found throughout the image. Here, pink represents low energy X-rays observed by Chandra, purple represents medium energy X-rays, and blue represents high energy X-rays.

Near our lower right, where the jet is at its thinnest, is a distinct pink "V", its arms opening toward our lower right. This mark is understood to be the result of the jet striking an unidentified object that lay in its path. A labeled version of the image highlights this region, and names the point of the V-shape, the incognito object, C4. A wide view version of the image is composited with optical data.

At the distance of Cen A, the arms of the V-shape appear rather small. In fact, each arm is at least 700 light-years long. The jet itself is 30,000 light-years long. For context, the nearest star to the Sun is about 4 light-years away.



Fast Facts for Centaurus A Knots:

Scale: Image is about 3 arcmin (11,000 light-years) across.
Category: Quasars & Active Galaxies
Coordinates (J2000): RA 13h 25m 27.62s | Dec -43° 01´ 08.80"
Constellation: Centaurus
Observation Dates: 34 observations between 17 May 2000 and 9 Sept 2022
Observation Time: 233 hours 18 minutes (9 days 17 hours 18 minutes)
Obs. ID: 962, 2978, 3965, 8489, 8490, 10722, 10725, 11846, 12156, 13303, 15294, 16276, 17890, 17891, 18461, 19747, 19521, 20794, 21698, 22714, 23823, 24318-24326, 26405, 26453, 27344, 27345
Instrument: ACIS
References: Bogensberger, D. et al., 2024, ApJ, 974, 307; arXiv:2408.14078
Color Code: X-ray (Chandra): magenta, purple, blue


Sunday, December 15, 2024

Featured Image: Gamma Rays from Massive Stars

Gamma Rays from Massive Stars

This image shows the star-forming region RCW 38, which is located 5,500 light-years from Earth. At less than a million years old — and possibly as young as 100,000 years — RCW 38 is the youngest super star cluster in the Milky Way. In the image above, infrared light from the Spitzer Space Telescope is shown in red, X-rays from the Chandra X-ray Observatory are in green, and gamma rays from the Fermi Gamma-ray Space Telescope are in blue. Paarmita Pandey (The Ohio State University) and coauthors recently observed this cluster in order to test the hypothesis that the outflowing winds of massive stars are a source of cosmic rays: charged particles traveling near the speed of light. Cosmic rays might be generated when winds from several stars crash into one another or into the gas of the interstellar medium. Pandey’s team hoped to find evidence for this process in the form of gamma rays, which are produced when cosmic rays collide with other particles. Using data from Fermi, the team found clear evidence of gamma rays coming from the region, adding to the small but growing number of young star clusters that are known to be associated with gamma-ray production. To learn more about this work, be sure to check out the full study linked below.


Citation

“Constraining the Diffusion Coefficient and Cosmic-Ray Acceleration Efficiency Using Gamma-Ray Emission from the Star-Forming Region RCW 38,” Paarmita Pandey et al 2024 ApJ 976 98. doi:10.3847/1538-4357/ad83bc



What’s in a nebula’s name?

Gum 40, IC2872, Running Chicken Nebula
Credit: ESO/VPHAS+ team.

Do you see a playful fox, a skulking hyena or… a chicken’s head? Located in the Centaurus constellation, this gas cloud is part of the giant Running Chicken Nebula. Some people see it as the head of the chicken, others see the chicken’s rear end.

But as much as scientists love fun names for nebulae, they are often not very conducive to clear communication in an international field like astronomy. That is why this nebula is formally known by two names that sound, well… a little less funky.

In 1955, Australian astronomer Colin Stanley Gum made an inventory of 84 emission nebulae in the southern sky: the Gum catalog. This one is known, quite dryly, as Gum 40. Long before Gum, in 1888, Danish astronomer John Louis Emil Dreyer had already compiled the ambitious New General Catalogue of Nebulae and Clusters of Stars (NGC), an index of 7840 astronomical objects such as galaxies, star clusters and emission nebulae like this one. Dreyer later added two Index Catalogues (IC) to his work, describing another 5386 celestial objects. This nebula was labelled IC 2872. The NGC is still used today: it got its most recent update in 2019, with 13 957 new objects.

This image of IC 2872 — or Gum 40, the chicken head or whatever nickname you might wish to give it — was captured by the VLT Survey Telescope (VST), hosted at ESO’s Paranal Observatory in Chile. As telescopes and instruments keep getting better, more and more deep-sky objects are discovered, so the lists and catalogues will never be complete. But that shouldn't keep us from trying to compile them — or making up fun nicknames, right?

Source: ESO/potw