Tuesday, February 28, 2023

Over One Billion Galaxies Blaze Bright in Colossal Map of the Sky

Image of Abell 3158, Part of the DESI Legacy Imaging Survey
 
The largest two-dimensional map of the sky ever made has grown even larger with the tenth data release from the DESI Legacy Imaging Surveys — a monumental six-year survey covering nearly half the sky. This new data release adds increased sky and wavelength coverage to the already completed surveys made with data from NSF’s NOIRLab telescopes at Kitt Peak National Observatory in Arizona and Cerro Tololo Inter-American Observatory in Chile.

The Universe is teeming with galaxies, each brimming with billions of stars. Though all galaxies shine brightly, many are cloaked in dust while others are so distant that to observers on Earth they appear as little more than faint smudges. By creating comprehensive maps of even the dimmest and most-distant galaxies, astronomers are better able to study the structure of the Universe and unravel the mysterious properties of dark matter and dark energy. The largest such map to date has just grown even larger, with the tenth data release from the DOE’s Dark Energy Spectroscopic Instrument (DESI) Legacy Imaging Survey

The DESI Legacy Imaging Survey expands on the data included in two earlier companion surveys: the Dark Energy Camera (DECam) Legacy Survey and the Beijing-Arizona Sky Survey. Jointly these three surveys imaged 14,000 square degrees of the sky visible from the northern hemisphere using telescopes at NSF’s NOIRLab’s Kitt Peak National Observatory (KPNO) and Cerro Tololo Inter-American Observatory (CTIO) in Chile. 

This ambitious six-year effort involved three telescopes, one petabyte (1000 trillion bytes) of data, and 100 million CPU hours on one of the world’s most powerful computers at the US Department of Energy’s National Energy Research Scientific Computing Center

This effort culminated in the largest two-dimensional map of the sky ever created. With collective observations by the Mosaic-3 camera on the Nicholas U. Mayall 4-meter Telescope and the 90Prime camera on the University of Arizona Bok 2.3-meter Telescope, both located at KPNO, as well as the DOE-built Dark Energy Camera (DECam) on the Víctor M. Blanco 4-meter Telescope at CTIO in Chile.

One of the main purposes of this map is to identify roughly 40 million target galaxies for the five-year DESI Spectroscopic Survey, which is aimed at understanding dark energy by precisely mapping the expansion history of the Universe over the last 12 billion years. The DESI project has selected its targets and the spectroscopic survey is currently underway. However, the team is looking to create the most comprehensive map of the sky that they can, so more images and improved processing have been added to the Legacy Surveys to include data that were previously missing.

Most notably, the tenth data release focuses on integrating new imaging from DECam of the southern extragalactic sky, especially in areas away from the Milky Way’s disk, which are ideal for looking far into the cosmos. 

With the addition of southern sky images in the new data release, the Legacy Surveys have been expanded to over 20,000 square degrees, nearly half the sky. In addition, the new release includes images of the sky taken in an additional color filter, able to sample infrared light just redder than what the human eye can see. The additions to the map’s footprint and wavelength coverage will in turn make the data useful to a wider demographic of scientists.

The addition of near-infrared wavelength data to the Legacy Survey will allow us to better calculate the redshifts of distant galaxies, or the amount of time it took light from those galaxies to reach Earth,” said Alfredo Zenteno, an astronomer with NSF’s NOIRLab and principal investigator of DECam eROSITA Survey (DeROSITAS).

“This is essential for surveys at radio and X-ray wavelengths that need the complete ‘optical’ view to identify the origin of the emission, like clusters of galaxies and active supermassive black holes,” said Mara Salvato, a researcher at the Max Planck Institute for Extraterrestrial Physics (MPE) and spokesperson for eROSITA.

The bulk of these additional DECam observations are from the DeROSITAS team, which includes scientists from NSF’s NOIRLab, the University of La Serena, MPE and Ludwig Maximilians University Munich in Germany; the DECam Local Volume Exploration Survey; and the final (sixth) year of the Dark Energy Survey. The team also scoured the NSF NOIRLab data archive to use any public data of the sky that already existed or was being collected by other researchers.

It’s not only scientists who benefit from the growing archive of astronomical data coming out of the Legacy Surveys. The publicly available data make it possible for astronomy enthusiasts and curious individuals to digitally peruse the Universe around us.

“Anyone can use the survey data to explore the sky and make discoveries,” said Arjun Dey, an astronomer with NSF’s NOIRLab. “In my opinion it is this ease of access which has made this survey so impactful. We hope that in a few years the Legacy Surveys will have the most complete map of the entire sky, and provide a treasure trove for scientists well into the future.”

NOIRLab will host these data products in the Astro Data Archive, from the original images taken at the telescopes to the catalogs that report the positions and other properties of stars and galaxies. Astro Data Lab, which is part of the Community Science and Data Center (CSDC) at NSF’s NOIRLab, also serves the catalogs as databases, which astronomers can easily analyze using the Astro Data Lab tools and services, and cross-match them with other datasets, giving more opportunities for discovery. In addition, Astro Data Lab provides astronomers with example scientific applications and tutorials to assist with their research.

More information

NSF’s NOIRLab (National Optical-Infrared Astronomy Research Laboratory), the US 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), Kitt Peak National Observatory (KPNO), Cerro Tololo Inter-American Observatory (CTIO), the Community Science and Data Center (CSDC), and Vera C. Rubin Observatory (operated in cooperation with the Department of Energy’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 astronomical community is honored to have the opportunity to conduct astronomical research on Iolkam 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 that these sites have to the Tohono O’odham Nation, to the Native Hawaiian community, and to the local communities in Chile, respectively.

DESI is supported by the US Department of Energy’s Office of High Energy Physics; the US National Science Foundation, Division of Astronomical Sciences under contract to the NSF’s NOIRLab; the Science and Technologies Facilities Council of the United Kingdom; the Gordon and Betty Moore Foundation; the Heising-Simons Foundation; the French Alternative Energies and Atomic Energy Commission (CEA); the National Council of Science and Technology of Mexico; the Ministry of Economy of Spain; and DESI member institutions. The DESI scientists are honored to be permitted to conduct astronomical research on Iolkam Du’ag (Kitt Peak), a mountain with particular significance to the Tohono O'odham Nation.

For more information, visit: desi.lbl.gov.

Contacts:

Charles Blue
Public Information Officer
NSF’s NOIRLab
Tel: +1 202 236 6324
Email:
charles.blue@noirlab.edu

 

Source:  NSF’s National Optical-Infrared Astronomy Research Laboratory (NOIRLab)/News


Monday, February 27, 2023

A Fresh Look at Kepler-444’s Ancient Planetary System

Artist's impression of a star orbited by five planets
Credits: NASA/JPL-Caltech

Astronomers have just taken a closer look at an unusual system containing three stars and at least five planets. In doing so they may have solved a mystery around its formation. The system, known as Kepler-444, is also around 11 billion years old, showing that such systems can be stable over a significant fraction of the universe’s current age.

Typical observation of the central star Kepler-444 A and the binary pair Kepler-444 BC
Credit: Adapted fromZhang et al. 2023

One System, Three Stars, Five Planets

Located 117 light-years away toward the constellation Lyra, the system is centered around the K0 star Kepler-444 A. Then there’s a tight-knit binary pair of M-type stars orbiting it some 66 astronomical units away (known as Kepler-444 BC). A quintet of planets also orbits Kepler-444 A. All five worlds have radii between 0.4 and 0.7 Earth radius, and every one has an orbital period under 10 days.

A team of astronomers led by Zhoujian Zhang (University of California, Santa Cruz) recently set about measuring the properties of the crowded system more precisely in several different ways. They used the High Resolution Spectrograph of the Hobby-Eberly Telescope at the McDonald Observatory in Texas to measure Kepler-444 A’s radial velocity. The star’s speed changes as it is pulled around by the other objects in the system. Zhang’s team also measured the relative radial velocities between the binary pair and the central star using the High Resolution Echelle Spectrometer at the W. M. Keck Observatory in Hawaii.

The gravitational pull of its companions causes Kepler-444 A to follow a wiggling path across the night sky. Measuring this changing position is known as astrometry. Zhang’s team conducted astrometric measurements of Kepler-444 A using Keck’s near-infrared imager (NIRC2).

T


op panel: Observed (orange circles) and modeled (green lines) separations between Kepler-444 A and Kepler-444 BC. The black line shows the best-fitting model. Bottom panel: Observed values minus modeled values. Credit: Adapted from
Zhang et al. 2023

Expanding Planet-Forming Potential

Putting all these pieces of the puzzle together, the team arrived at a deeper understanding of the Kepler-444 system and its history. Previous measurements of the system suggested that the binary swings in to within 5 astronomical units of Kepler-444 A. That would have truncated Kepler-444 A’s protoplanetary disk, severely depleting the amount of planet-forming material available. It wasn’t clear how five rocky planets could have formed there.

Now, based on their new measurements, Zhang’s team conclude that the Kepler-444 BC binary only gets within 23 astronomical units of Kepler-444 A. This wider separation would have led to a larger and more massive protoplanetary disk truncated to 8 astronomical units. The team calculate that there would have been 500 solar masses’ worth of dust available from which to build planets. That compares to just 4 solar masses of dust using previous estimates. Suddenly the presence of five planets is less perplexing.

As astronomers gain a greater understanding of exoplanets, it’s becoming clear that there’s more than one way to make a solar system.

Citation :

“The McDonald Accelerating Stars Survey: Architecture of the Ancient Five-planet Host System Kepler-444,” Zhoujian Zhang et al 2023 AJ 165 73. doi:10.3847/1538-3881/aca88c

 By Colin Stuart

Source:  American Astronomical Society/ASS - Nova


Friday, February 24, 2023

The Swansong of a Cloud Approaching the Milky Way’s Supermassive Black Hole


Keck Observatory nirc2 and adaptive optics image taken in summer 2021 showing the gas and dust structures in the galactic center, including g objects and x7.Credit: A. Ciurlo et al./UCLA GCOI/W. M. Keck Observatory 

Maunakea, Hawaiʻi Two decades of monitoring from W. M. Keck Observatory on Maunakea in Hawaiʻi reveals a peculiar cloud being pulled apart as it accelerates toward the supermassive black hole at the center of our Milky Way galaxy.

Dubbed X7, astronomers from the UCLA Galactic Center Orbits Initiative (GCOI) and Keck Observatory have been tracking the evolution of this dusty gas filament since 2002; high-angular resolution near-infrared images captured with Keck Observatory’s powerful adaptive optics system show X7 has become so elongated, it now has a length of 3,000 times the distance between the Earth and Sun (or 3,000 astronomical units).

The study is published in today’s issue of The Astrophysical Journal.

“This is a unique chance at observing the effects of the black hole’s tidal forces at high-resolution, giving us insight into the physics of the Galactic Center’s extreme environment,” said Anna Ciurlo, a UCLA assistant researcher and lead author of the study.

Images captured with Keck Observatory’s NIRC2 instrument and adaptive optics showing X7’s evolution between 2002-2021. Credit: A. Ciurlo et al./UCLA GCOI/W. M. Keck Observatory

Tidal forces are the gravitational pull that stretch an object approaching a black hole; the side of the object closest to the black hole is pulled much more strongly than the side farthest away.

“It’s exciting to see significant changes of X7’s shape and dynamics in such great detail over a relatively short time scale as the gravitational forces of the supermassive black hole at the center of the Milky Way influences this object,” said co-author Randy Campbell, science operations lead at Keck Observatory.

X7 has a mass of about 50 Earths and is on an orbital path around our galaxy’s black hole, called Sagittarius A* (or Sgr A*), that would take 170 years to complete.

“We anticipate the strong tidal forces exerted by the Galactic black hole will ultimately tear X7 apart before it completes even one orbit,” said co-author Mark Morris, UCLA professor of physics and astronomy.

Based on its trajectory, the team estimates X7 will make its closest approach to Sgr A* around the year 2036, then dissipate completely soon after. The gas and dust constituting X7 will eventually get dragged toward Sgr A* and may later cause some fireworks as it heats up and spirals into the black hole.


The Swansong of X7 from Keck Observatory on Vimeo.

Artist’s rendering of what is anticipated to happen around the year 2036 when X7, an elongated filament of dust and gas, makes its closest approach to the Milky Way’s supermassive black hole. Credit: W. M. Keck Observatory/Adam Makarenko


These findings are the first estimate of X7’s mildly eccentric orbital path and most robust analysis to date of the remarkable changes to its appearance, shape, and behavior. To observe X7, the team used Keck Observatory’s OH-Suppressing Infrared Imaging Spectrograph (OSIRIS) and Near-Infrared Camera, second generation (NIRC2), in combination with the adaptive optics systems on the Keck I and Keck II telescopes.

X7 shows some of the same observational properties as the other strange dusty objects orbiting Sgr A* called G objects, which look like gas but behave like stars. However, X7’s shape and velocity structure has morphed more dramatically compared to the G objects. The stretched-out gas and dust filament moves rapidly, clocking in at speeds of up to 490 miles per second. Because of the extremely large mass of the black hole, everything in its vicinity moves much faster than we typically see anywhere else in our galaxy.

Though X7’s origin is still a secret waiting to be unlocked and confirmed, the research team does have some clues about its possible formation.

“One possibility is that X7’s gas and dust were ejected at the moment when two stars merged,” said Ciurlo. “In this process, the merged star is hidden inside a shell of dust and gas, which might fit the description of the G objects. And the ejected gas perhaps produced X7-like objects.”

The research team will continue to monitor the dramatic changes of X7 with Keck Observatory as the power of the black hole’s gravity yanks it apart.

“It’s a privilege to be able to study the extreme environment at the center of our galaxy,” said Campbell. “This study can only be done using Keck’s superb capabilities and performed at the revered Maunakea, with honor and respect for this special site.”

Source:  W.M. Keck Observatory



About GCOI

The Galactic Center Orbits Initiative (GCOI), is an Adaptive Optics (AO) study of our Galaxy’s supermassive black hole (SMBH) and its environs. This long-term program has been collecting AO data with the W.M. Keck Observatory for over 25 years. The GCOI has opened up a new approach to studying the physics and astrophysics of supermassive black hole through the measurement of stellar orbits. This unique dataset is enabling us to gain new insights into how gravity works near a supermassive black hole and unique astrophysical events.

About ADAPTIVE OPTICS

W. M. Keck Observatory is a distinguished leader in the field of adaptive optics (AO), a breakthrough technology that removes the distortions caused by the turbulence in the Earth’s atmosphere.  Keck Observatory pioneered the astronomical use of both natural guide star (NGS) and laser guide star adaptive optics (LGS AO) and current systems now deliver images three to four times sharper than the Hubble Space Telescope at near-infrared wavelengths. AO has imaged the four massive planets orbiting the star HR8799, measured the mass of the giant black hole at the center of our Milky Way Galaxy, discovered new supernovae in distant galaxies, and identified the specific stars that were their progenitors. Support for this technology was generously provided by the Bob and Renee Parsons Foundation, Change Happens Foundation, Gordon and Betty Moore Foundation, Mt. Cuba Astronomical Foundation, NASA, NSF, and W. M. Keck Foundation.

About NIRC2

The Near-Infrared Camera, second generation (NIRC2) works in combination with the Keck II adaptive optics system to obtain very sharp images at near-infrared wavelengths, achieving spatial resolutions comparable to or better than those achieved by the Hubble Space Telescope at optical wavelengths. NIRC2 is probably best known for helping to provide definitive proof of a central massive black hole at the center of our galaxy. Astronomers also use NIRC2 to map surface features of solar system bodies, detect planets orbiting other stars, and study detailed morphology of distant galaxies. 

About OSIRIS

The OH-Suppressing Infrared Imaging Spectrograph (OSIRIS) is one of W. M. Keck Observatory’s “integral field spectrographs.” The instrument works behind the adaptive optics system, and uses an array of lenslets to sample a small rectangular patch of the sky at resolutions approaching the diffraction limit of the 10-meter Keck Telescope. OSIRIS records an infrared spectrum at each point within the patch in a single exposure, greatly enhancing its efficiency and precision when observing small objects such as distant galaxies. It is used to characterize the dynamics and composition of early stages of galaxy formation. Support for this technology was generously provided by the Heising-Simons Foundation and the National Science Foundation.

About W. M. Keck Observatory

The W. M. Keck Observatory telescopes are among the most scientifically productive on Earth. The two 10-meter optical/infrared telescopes atop Maunakea on the Island of Hawaii feature a suite of advanced instruments including imagers, multi-object spectrographs, high-resolution spectrographs, integral-field spectrometers, and world-leading laser guide star adaptive optics systems. Some of the data presented herein were obtained at Keck Observatory, which is a private 501(c) 3 non-profit organization operated as a scientific partnership among the California Institute of Technology, the University of California, and the National Aeronautics and Space Administration. The Observatory was made possible by the generous financial support of the W. M. Keck Foundation. The authors wish to recognize and acknowledge the very significant cultural role and reverence that the summit of Maunakea has always had within the Native Hawaiian community. We are most fortunate to have the opportunity to conduct observations from this mountain.



Thursday, February 23, 2023

Spotting a hidden exoplanet

AF Leporis
Credit: ESO/Mesa, De Rosa et al.

No, you’re not seeing double: this Picture of the Week shows two images of a Jupiter-like planet that orbits the star AF Leporis. The planet has been imaged by two independent groups of astronomers using the SPHERE instrument on ESO’s Very Large Telescope (VLT) in Chile. But why did they target this particular star?

The two groups, led by Dino Mesa (INAF, Italy) and Robert De Rosa (ESO, Chile), studied star catalogues from the European Space Agency’s Hipparcos and Gaia satellites. Over the years, these two space missions have accurately pinpointed the position and motion of stars in our galaxy using astrometry. Planets exert a gravitational tug on their host stars, perturbing their trajectory on the sky. The two teams found that the star AF Leporis exhibited such a disturbed trajectory, a telltale sign that a planet could be hiding there.

As the two groups took a closer look at this system with the VLT, they managed to directly image the planet that orbits AF Leporis. They both used the SPHERE instrument, which corrects the blurring caused by atmospheric turbulence using adaptive optics, and also blocks the light from the star with a special mask, revealing the planet next to it. They found that the planet is just a few times more massive than Jupiter, making it the lightest exoplanet detected with the combined use of astrometric measurements and direct imaging.

The AF Leporis system shares similar features to our Solar System. The star has roughly the same mass, size and temperature as the Sun, and the planet orbits it at a distance similar to that between Saturn and the Sun. The system also has a debris belt with similar characteristics as the Kuiper belt. Since the AF Leporis system is only 24 million years old ––about 200 times younger than the Sun–– further studies of this system can shed light on how our own Solar System was formed.

Links

Source:  ESO/potw


Wednesday, February 22, 2023

Black Hole Pairs: NASA's Chandra Discovers Giant Black Holes on Collision Course

Mirabilis, Elstir, Vinteuil, Labeled
Credit: X-ray: NASA/CXC/Univ. of Alabama/M. Micic et al.;/div>
Optical: International Gemini Observatory/NOIRLab/NSF/AURA

A Tour of Giant Black Holes on Collision Course - More Videos


A new study using NASA’s Chandra X-ray Observatory has tracked two pairs of supermassive black holes in dwarf galaxies on collision courses, as discussed in our latest press release. This is the first evidence for such an impending encounter, providing scientists with important information about the growth of black holes in the early Universe.

By definition, dwarf galaxies contain stars with a total mass less than 3 billion Suns — or about 20 times less than the Milky Way. Astronomers have long suspected that dwarf galaxies merge, particularly in the relatively early Universe, in order to grow into the larger galaxies seen today. However, current technology cannot observe the first generation of dwarf galaxy mergers because they are extraordinarily faint at their great distances. Another tactic — looking for dwarf galaxy mergers closer by — had not been successful to date.

The new study overcame these challenges by implementing a systematic survey of deep Chandra X-ray observations and comparing them with infrared data from NASA’s Wide Infrared Survey Explorer (WISE) and optical data from the Canada-France-Hawaii Telescope (CFHT).

Chandra was particularly valuable for this study because material surrounding black holes can be heated up to millions of degrees, producing large amounts of X-rays. The team searched for pairs of bright X-ray sources in colliding dwarf galaxies as evidence of two black holes, and discovered two examples.

One pair is in the galaxy cluster Abell 133 located 760 million light-years from Earth, seen in the composite image on the left. Chandra X-ray data is in pink and optical data from CFHT is in blue. This pair of dwarf galaxies appears to be in the late stages of a merger, and shows a long tail caused by tidal effects from the collision. The authors of the new study have nicknamed it “Mirabilis” after an endangered species of hummingbird known for their exceptionally long tails. Only one name was chosen because the merger of two galaxies into one is almost complete. The two Chandra sources show X-rays from material around the black holes in each galaxy.

The other pair was discovered in Abell 1758S, a galaxy cluster about 3.2 billion light-years away. The composite image from Chandra and CFHT is on the right, using the same colors as for Mirabilis. The researchers nicknamed the merging dwarf galaxies “Elstir” and “Vinteuil,” after fictional artists from Marcel Proust's "In Search of Lost Time". Vinteuil is the galaxy on the top and Elstir is the galaxy on the bottom. Both have Chandra sources associated with them, again from X-rays from material around the black holes in each galaxy. The researchers think these two have been caught in the early stages of a merger, causing a bridge of stars and gas to connect the two colliding galaxies from their gravitational interaction.

The details of merging black holes and dwarf galaxies may provide insight to our Milky Way’s own past. Scientists think nearly all galaxies began as dwarf or other types of small galaxies and grew over billions of years through mergers. Follow-up observations of these two systems will allow astronomers to study processes that are crucial for understanding galaxies and their black holes in the earliest stages of the Universe.

A paper describing these results is being published in the latest issue of The Astrophysical Journal and a preprint is available here. The authors of the study are Marko Micic, Olivia Holmes, Brenna Wells, and Jimmy Irwin, all from the University of Alabama at Tuscaloosa.

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.

The other pair was discovered in Abell 1758S, a galaxy cluster about 3.2 billion light-years away. The composite image from Chandra and CFHT is on the right, using the same colors as for Mirabilis. The researchers nicknamed the merging dwarf galaxies “Elstir” and “Vinteuil,” after fictional artists from Marcel Proust's "In Search of Lost Time". Vinteuil is the galaxy on the top and Elstir is the galaxy on the bottom. Both have Chandra sources associated with them, again from X-rays from material around the black holes in each galaxy. The researchers think these two have been caught in the early stages of a merger, causing a bridge of stars and gas to connect the two colliding galaxies from their gravitational interaction.

The details of merging black holes and dwarf galaxies may provide insight to our Milky Way’s own past. Scientists think nearly all galaxies began as dwarf or other types of small galaxies and grew over billions of years through mergers. Follow-up observations of these two systems will allow astronomers to study processes that are crucial for understanding galaxies and their black holes in the earliest stages of the Universe.

A paper describing these results is being published in the latest issue of The Astrophysical Journal and a preprint is available here. The authors of the study are Marko Micic, Olivia Holmes, Brenna Wells, and Jimmy Irwin, all from the University of Alabama at Tuscaloosa.

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.






Visual Description:

This release includes two composite images presented side by side, separated by a thin white line. The image on our left features two colliding dwarf galaxies in the late stages of merging into one larger galaxy. The image on our right features two colliding dwarf galaxies in the early stages of merging.

In the first pair of dwarf galaxies, on our left, a pale pink shape sits inside a hazy indigo blue cloud. The cloud contains neon pink streaks, and faint white specks. This cloud represents gas and stars in the merging galaxies. The pale pink shape at its core represents a black hole being tracked by the Chandra X-ray Observatory. Directly above the cloud is a neon pink and indigo circle, representing another black hole, followed by a curving tail of hazy indigo circles flecked with white. This tail, which curves up and to our right, is caused by tidal effects from the ongoing collision. Because these two dwarf galaxies are in the final stages of merging, scientists have given the combined galaxy a single name: Mirabilis.

In the second pair of dwarf galaxies, on our right, a neon pink cloud with a bright white circle at its core, sits above a larger companion with the same color configuration. These pink clouds are the dwarf galaxies known as Vinteuil and Elstir. The white cores represent black holes tracked by Chandra. Elstir, the larger neon pink cloud, near the bottom, features wispy tendrils. Several of these tendrils appear to reach up toward the smaller galaxy, Vinteuil, creating a bridge of gas and stars.



Fast Facts for Mirabilis:

Scale: Image is about 14 arcseconds (50,000 light-years) across.
Category::
Black Holes, Quasars & Active Galaxies Coordinates (J2000): RA 01h 01m 36.7s | Dec -21° 37´ 48.5"
Constellation: Cetus   
Observation Date: June 6th, Sept 9, and Sept 10, 2011
Observation Time: 44 hours (2 days 20 hours)
Obs. ID: 13446, 13449, 14338
Instrument: ACIS
References: Micic, M., et al., 2023, ApJ, in press; arXiv:2211.04609
Colr Code:
X-ray: pink; Optical: blue

Distace Estimate: About 760 million light-years

Fast Facts for Elstir and Vinteuil:

Scale: Image is about 10 arcsec (140,000 light-years) across.
Category: Black Holes, Quasars & Active Galaxies
Coordinates (J2000): RA 13h 33m 0.3s | Dec +50° 23´ 32.2"
Constellation: Canes Venatici
Observation Date: Sept 27, Sept 28 and Oct 9th, 2012
Observation Time: 41 hours (1 day 17 hours)
Obs. ID: 13997, 15538, 15540
Instrument: ACIS
References: Micic, M., et al., 2023, ApJ, in press; arXiv:2211.04609
Color Code: X-ray: pink; Optical: blue
Distance Estimate: About 3.2 billion light-years



Tuesday, February 21, 2023

Cosmic Contortions


A cluster of large galaxies, surrounded by various stars and smaller galaxies on a dark background. The central cluster is mostly made of bright elliptical galaxies that are surrounded by a warm glow. Nearby the cluster is the stretched, distorted arc of a galaxy, gravitationally lensed by the cluster. Credit: ESA/Hubble & NASA, H. Ebeling

A massive galaxy cluster in the constellation Cetus dominates the centre of this image from the NASA/ESA Hubble Space Telescope. This image is populated with a serene collection of elliptical and spiral galaxies, but galaxies surrounding the central cluster — which is named SPT-CL J0019-2026 — appear stretched into bright arcs, as if distorted by a gargantuan magnifying glass. This cosmic contortion is called gravitational lensing, and it occurs when a massive object like a galaxy cluster has a sufficiently powerful gravitational field to distort and magnify the light from background objects. Gravitational lenses magnify light from objects that would usually be too distant and faint to observe, and so these lenses can extend Hubble’s view even deeper into the Universe.

This observation is part of an ongoing project to fill short gaps in Hubble’s observing schedule by systematically exploring the most massive galaxy clusters in the distant Universe, in the hopes of identifying promising targets for further study with both Hubble and the NASA/ESA/CSA James Webb Space Telescope. This particular galaxy cluster lies at a vast distance of 4.6 billion light years from Earth.

Each year, the Space Telescope Science Institute is inundated with observing proposals for Hubble, in which astronomers suggest targets for observation. Even after selecting only the very best proposals, scheduling observations of all of Hubble’s targets for a year is a formidable task. There is sometimes a small fraction of observing time left unused in Hubble’s schedule, so in its ‘spare time’ the telescope has a collection of objects to explore — including the lensing galaxy cluster shown in this image.

[Image description: A cluster of large galaxies, surrounded by various stars and smaller galaxies on a dark background. The central cluster is mostly made of bright elliptical galaxies that are surrounded by a warm glow. Nearby the cluster is the stretched, distorted arc of a galaxy, gravitationally lensed by the cluster.]

Source:  ESA/Hubble/potw



Monday, February 20, 2023

New Aurorae Detected on Jupiter’s Four Largest Moons

Artist’s rendition of oxygen, sodium, and potassium aurorae as io enters jupiter’s shadow.
Credit: Chris Faust


Maunakea, Hawaiʻi – Astronomers using W. M. Keck Observatory on Maunakea in Hawaiʻi have discovered that aurorae at visible wavelengths appear on all 4 major moons of Jupiter: Io, Europa, Ganymede, and Callisto.

Using Keck Observatory’s High-Resolution Echelle Spectrometer (HIRES) as well as high-resolution spectrographs at the Large Binocular Telescope and Apache Point Observatory, a team led by Caltech and Boston University observed the moons in Jupiter’s shadow so that their faint aurorae, which are caused by the gas giant’s strong magnetic field, could be spotted without competition from bright sunlight reflected off of their surfaces.

“These observations are tricky because in Jupiter’s shadow the moons are nearly invisible. The light emitted by their faint aurorae is the only confirmation that we’ve even pointed the telescope at the right place,” says Katherine de Kleer, Caltech professor and lead author of one of two new research papers published today in the Planetary Science Journal describing the discovery.

All four of the Galilean moons show the same oxygen aurora we see in skies near the Earth’s poles, but gases on Jupiter’s moons are much thinner, allowing a deep red color to glow nearly 15 times brighter than the familiar green light.

At Europa and Ganymede, oxygen also lights up infrared wavelengths, just a little redder than the human eye can see – the first occurrence of this phenomenon seen in the atmosphere of a body other than Earth.

At Io, Jupiter’s innermost moon, volcanic plumes of gas and dust are vast in size, reaching hundreds of kilometers in height. These plumes contain salts like sodium chloride and potassium chloride, which break down to produce additional colors. Sodium gives Io’s aurora the same yellowy-orange glow that we see in urban streetlamps. The new measurements also show potassium aurora at Io in infrared light, which has not been detected anywhere else previously.

“The brightness of the different colors of aurora tell us what these moons’ atmospheres are likely made up of,” said de Kleer. “We find that molecular oxygen, just like what we breathe here on Earth, is likely the main constituent of the icy moon atmospheres.”

The new measurements show minimal evidence for water, fueling an active scientific debate over whether the atmospheres of Jupiter’s moons feature significant water vapor. It’s currently believed that the outer 3 Galilean moons of Jupiter contain oceans of liquid water beneath their thick icy surfaces, and there’s tentative evidence that water in Europa’s atmosphere may sometimes be sourced from its ocean or liquid reservoirs within its ice shell.

A

rtist’s depiction of oxygen aurora on Jupiter’s moon Ganymede, the largest moon in the solar system, as observed from Maunakea on Hawaiʻi Island using the twin Keck Observatory telescopes.  Credit: Julie Inglis
 
Since Jupiter’s strong magnetic field is tilted, aurorae on these moons change in brightness as the planet rotates. Additionally, the atmospheres can respond to the rapid transition from warm sunlight to the cold shadow of Jupiter.

“Io’s sodium becomes very faint within 15 minutes of entering Jupiter’s shadow, but it takes several hours to recover after it emerges into sunlight,” explains Carl Schmidt, Astronomy Professor at Boston University and lead author of the second paper. “These new characteristics are really insightful for understanding Io’s atmospheric chemistry. It’s neat that eclipses by Jupiter offer a natural experiment to learn how sunlight affects its atmosphere.”

New types of aurora on the four moons add an exciting aspect to what is already a golden age for fans of Jupiter thanks to NASA’s Juno mission and the James Webb Space Telescope. If you’re lucky enough to see the aurora here on Earth, pause to consider how amazing the show might appear if you were looking up from one of Jupiter’s moons.

The first paper about this research, led by de Kleer, is titled “The Optical Aurorae of Europa, Ganymede, and Callisto.” The second paper, led by Schmidt, is titled “Io’s Optical Aurorae in Jupiter’s Shadow.”




About HIRES

The High-Resolution Echelle Spectrometer (HIRES) produces spectra of single objects at very high spectral resolution, yet covering a wide wavelength range. It does this by separating the light into many “stripes” of spectra stacked across a mosaic of three large CCD detectors. HIRES is famous for finding exoplanets. Astronomers also use HIRES to study important astrophysical phenomena like distant galaxies and quasars, and find cosmological clues about the structure of the early universe, just after the Big Bang.



About W. M. Keck Observatory


The W. M. Keck Observatory telescopes are among the most scientifically productive on Earth. The two 10-meter optical/infrared telescopes atop Maunakea on the Island of Hawaii feature a suite of advanced instruments including imagers, multi-object spectrographs, high-resolution spectrographs, integral-field spectrometers, and world-leading laser guide star adaptive optics systems. Some of the data presented herein were obtained at Keck Observatory, which is a private 501(c) 3 non-profit organization operated as a scientific partnership among the California Institute of Technology, the University of California, and the National Aeronautics and Space Administration. The Observatory was made possible by the generous financial support of the W. M. Keck Foundation. The authors wish to recognize and acknowledge the very significant cultural role and reverence that the summit of Maunakea has always had within the Native Hawaiian community. We are most fortunate to have the opportunity to conduct observations from this mountain.


Saturday, February 18, 2023

12 New Jovian Moons Discovered


Figure 1: Conceptual diagram showing the orbits of Jupiter's satellites. The left and right figures represent Jupiter viewed from the polar and equatorial directions, respectively. The gray (innermost), pink, yellow, blue, light blue, green, and red lines represent the orbits of Amalthea group, Galilean satellites, Themisto, Himalia group, Carpo, Valetudo, and retrogrades, respectively.. Credit: Scott Shepard/Carnegie Institution for Science

Observations using the Subaru Telescope and other telescopes led to the discovery of swarms of potential new moons around Jupiter. Of these, 12 have been confirmed as moons of Jupiter, and many more are awaiting further observations for confirmation.

A team, led by Scott Sheppard at the Carnegie Institute for Science, noticed that Jupiter was near their target field locations while searching for new objects in the outer Solar System beyond Pluto. So the team decided to look for new Jovian moons in the foreground while looking for new outer-Solar-System objects in the background. They performed their observations with the Subaru Telescope in September 2021 and the Blanco 4-meter Telescope with the Dark Energy Camera in August 2022.

The team’s ingenuity was rewarded with many new candidates. Follow-up observations using the 6.5-meter Magellan Telescopes in Chile characterized 12 of those candidates well enough to be declared moons. They will now be given official numbers and names. The team will continue to monitor the additional candidates to see if they can increase the number of known moons even more.

The newly confirmed satellites bring the number of known moons around Jupiter to 92, exceeding the 83 known moons around Saturn. But caution is needed in making direct comparisons. Because Saturn is farther away, it is more difficult to spot small, faint satellites around it. Sheppard comments, "We believe when comparing moons of the same size range, Saturn has more than Jupiter, but both planets have many, many of these small moons."

One motivation to look for new moons around Jupiter is that ESA’s JUICE (JUpiter ICy moons Explorer) and NASA’s Europa Clipper spacecraft are planned to enter the Jovian system in the near future. Sheppard explains, "The hope is that if we find enough moons, one of them will just happen to be close enough to the spacecraft’s trajectory to get close-up flyby images of it while the spacecraft is passing through the outer Jovian system to the inner Jovian system."

These findings were announced in late January by the International Astronomical Union’s Minor Planet Center.

Maunakea, which has cultural, historical, and natural significance in Hawai`i.

Relevant Links

SourceSubaru Telescope


Friday, February 17, 2023

Tadpole Playing Around Black Hole

Artist’s Impression of the “Tadpole” Molecular Cloud and the black hole at the gravitational center of its orbit.
Credit: Keio University.
Original size (1.3 MB)

A peculiar cloud of gas, nicknamed the Tadpole due to its shape, appears to be revolving around a space devoid of any bright objects. This suggests that the Tadpole is orbiting a dark object, most likely a black hole 100,000 times more massive than the Sun. Future observations will help determine what is responsible for the shape and motion of the Tadpole.

A team of Japanese researchers led by Miyuki Kaneko at Keio University used data from the James Clerk Maxwell Telescope, operated by the East Asian Observatory, and NAOJ’s Nobeyama 45-m Radio Telescope to identify an unusual cloud of gas about 27,000 light-years away in the constellation Sagittarius. The curved “Tadpole” shape of the molecular gas cloud strongly suggests that it is being stretched as it orbits around a massive compact object. The only problem is, at the center of the Tadpole’s orbit, there are no bright objects which could be massive enough to gravitationally hold the Tadpole. The best candidate for this massive compact invisible object is a black hole.

Because black holes don’t emit light, the only way to detect them is when they interact with other objects. This leaves astronomers in the dark about just how many black holes, and with what range of masses, might be lurking in the Milky Way.

Now the team plans to use ALMA (Atacama Large Millimeter/submillimeter Array) to search for faint signs of a black hole, or other object, at the gravitational center of the Tadpole’s orbit.

These results appeared as Kaneko et al. “Discovery of the Tadpole Molecular Cloud near the Galactic Nucleus” in The Astrophysical Journal on January 10, 2023.


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Thursday, February 16, 2023

NASA’s Webb Reveals Intricate Networks of Gas and Dust in Nearby Galaxies

NGC 1433 (MIRI Image)
Credits: Science: NASA, ESA, CSA, Janice Lee (NOIRLab)
Image Processing: Alyssa Pagan (STScI)

NGC 7496 (MIRI Image)
Science: NASA, ESA, CSA, Janice Lee (NOIRLab)
Image Processing: Joseph DePasquale (STScI)

NGC 1365 (MIRI Image)
Credits: Science: NASA, ESA, CSA, Janice Lee (NOIRLab)
Image Processing: Alyssa Pagan (STScI)




Researchers using NASA’s James Webb Space Telescope are getting their first look at star formation, gas, and dust in nearby galaxies with unprecedented resolution at infrared wavelengths. The data has enabled an initial collection of 21 research papers which provide new insight into how some of the smallest-scale processes in our universe – the beginnings of star formation – impact the evolution of the largest objects in our cosmos: galaxies.

The largest survey of nearby galaxies in Webb’s first year of science operations is being carried out by the Physics at High Angular resolution in Nearby Galaxies (PHANGS) collaboration, involving more than 100 researchers from around the globe. The Webb observations are led by Janice Lee, Gemini Observatory chief scientist at the National Science Foundation’s NOIRLab and affiliate astronomer at the University of Arizona in Tucson.

The team is studying a diverse sample of 19 spiral galaxies, and in Webb’s first few months of science operations, observations of five of those targets – M74, NGC 7496, IC 5332, NGC 1365, and NGC 1433 – have taken place. The results are already astounding astronomers.

“The clarity with which we are seeing the fine structure certainly caught us by surprise,” said team member David Thilker of Johns Hopkins University in Baltimore, Maryland.

“We are directly seeing how the energy from the formation of young stars affects the gas around them, and it’s just remarkable,” said team member Erik Rosolowsky of the University of Alberta, Canada.

The images from Webb’s Mid-Infrared Instrument (MIRI) reveal the presence of a network of highly structured features within these galaxies – glowing cavities of dust and huge cavernous bubbles of gas that line the spiral arms. In some regions of the nearby galaxies observed, this web of features appears built from both individual and overlapping shells and bubbles where young stars are releasing energy.

“Areas which are completely dark in Hubble imaging light up in exquisite detail in these new infrared images, allowing us to study how the dust in the interstellar medium has absorbed the light from forming stars and emitted it back out in the infrared, illuminating an intricate network of gas and dust,” said team member Karin Sandstrom of the University of California, San Diego.

The high-resolution imaging needed to study these structures has long evaded astronomers – until Webb came into the picture. “The PHANGS team has spent years observing these galaxies at optical, radio, and ultraviolent wavelengths using NASA’s Hubble Space Telescope, the Atacama Large Millimeter/Submillimeter Array, and the Very Large Telescope’s Multi Unit Spectroscopic Explorer,” added team member Adam Leroy of the Ohio State University. “But, the earliest stages of a star’s lifecycle have remained out of view because the process is enshrouded within gas and dust clouds.”

Webb’s powerful infrared capabilities can pierce through the dust to connect the missing puzzle pieces.

For example, specific wavelengths observable by MIRI (7.7 and 11.3 microns) and Webb’s Near-Infrared Camera (3.3 microns) are sensitive to emission from polycyclic aromatic hydrocarbons, which play a critical role in the formation of stars and planets. These molecules were detected by Webb in the first observations by the PHANGS program.

Studying these interactions at the finest scale can help provide insights into the larger picture of how galaxies have evolved over time.

“Because these observations are taken as part of what's called a treasury program, they are available to the public as they are observed and received on Earth,” said Eva Schinnerer of the Max Planck Institute for Astronomy in Heidelberg, Germany, and leader of the PHANGS collaboration.

The PHANGS team will work to create and release data sets that align Webb’s data to each of the complementary data sets obtained previously from the other observatories, to help accelerate discovery by the broader astronomical community.

“Thanks to the telescope's resolution, for the first time we can conduct a complete census of star formation, and take inventories of the interstellar medium bubble structures in nearby galaxies beyond the Local Group,” Lee said. “That census will help us understand how star formation and its feedback imprint themselves on the interstellar medium, then give rise to the next generation of stars, or how it actually impedes the next generation of stars from being formed.”

The research by the PHANGS team is being conducted as part of General Observer program 2107. The team’s initial findings, comprised of 21 individual studies, were recently published in a special focus issue of The Astrophysical Journal Letters.

The James Webb Space Telescope is the world's premier space science observatory. Webb will solve mysteries in our solar system, look beyond to distant worlds around other stars, and probe 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).




About This Release

Credits:

Media Contact:

Hannah Braun
Space Telescope Science Institute, Baltimore, Maryland

Christine Pulliam
Space Telescope Science Institute, Baltimore, Maryland

Science:

Janice Lee (NOIRLab), Eva Schinnerer

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Contact Us: Direct inquiries to the News Team.

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Wednesday, February 15, 2023

NASA’s Webb Uncovers New Details in Pandora’s Cluster

Pandora's Cluster (NIRCam Image)
Credits: Science: NASA, ESA, CSA, Ivo Labbe (Swinburne), Rachel Bezanson (University of Pittsburgh)
Image Processing: Alyssa Pagan (STScI)

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Astronomers have revealed the latest deep field image from NASA’s James Webb Space Telescope, featuring never-before-seen details in a region of space known as Pandora’s Cluster (Abell 2744). Webb’s view displays three clusters of galaxies – already massive – coming together to form a megacluster. The combined mass of the galaxy clusters creates a powerful gravitational lens, a natural magnification effect of gravity, allowing much more distant galaxies in the early universe to be observed by using the cluster like a magnifying glass.

Only Pandora’s central core has previously been studied in detail by NASA’s Hubble Space Telescope . By combining Webb’s powerful infrared instruments with a broad mosaic view of the region’s multiple areas of lensing, astronomers aimed to achieve a balance of breadth and depth that will open up a new frontier in the study of cosmology and galaxy evolution.

“The ancient myth of Pandora is about human curiosity and discoveries that delineate the past from the future, which I think is a fitting connection to the new realms of the universe Webb is opening up, including this deep-field image of Pandora’s Cluster,” said astronomer Rachel Bezanson of the University of Pittsburgh in Pennsylvania, co-principal investigator on the Ultradeep NIRSpec and NIRCam ObserVations before the Epoch of Reionization (UNCOVER) program to study the region.

“When the images of Pandora’s Cluster first came in from Webb, we were honestly a little star struck,” said Bezanson. “There was so much detail in the foreground cluster and so many distant lensed galaxies, I found myself getting lost in the image. Webb exceeded our expectations.” The new view of Pandora’s Cluster stitches four Webb snapshots together into one panoramic image, displaying roughly 50,000 sources of near-infrared light.

In addition to magnification, gravitational lensing distorts the appearance of distant galaxies, so they look very different than those in the foreground. The galaxy cluster “lens” is so massive that it warps the fabric of space itself, enough for light from distant galaxies that passes through that warped space to also take on a warped appearance.

Astronomer Ivo Labbe of the Swinburne University of Technology in Melbourne, Australia, co-principal investigator on the UNCOVER program, said that in the lensing core to the lower right in the Webb image, which has never been imaged by Hubble, Webb revealed hundreds of distant lensed galaxies that appear like faint arced lines in the image. Zooming in on the region reveals more and more of them.

“Pandora’s Cluster, as imaged by Webb, shows us a stronger, wider, deeper, better lens than we have ever seen before,” Labbe said. “My first reaction to the image was that it was so beautiful, it looked like a galaxy formation simulation. We had to remind ourselves that this was real data, and we are working in a new era of astronomy now.”

The UNCOVER team used Webb’s Near-Infrared Camera (NIRCam) to capture the cluster with exposures lasting 4-6 hours, for a total of about 30 hours of observing time. The next step is to meticulously go through the imaging data and select galaxies for follow-up observation with the Near-Infrared Spectrograph (NIRSpec), which will provide precise distance measurements, along with other detailed information about the lensed galaxies’ compositions, providing new insights into the early era of galaxy assembly and evolution. The UNCOVER team expects to make these NIRSpec observations in the summer of 2023.

In the meantime, all of the NIRCam photometric data has been publicly released so that other astronomers can become familiar with it and plan their own scientific studies with Webb’s rich datasets. “We are committed to helping the astronomy community make the best use of the fantastic resource we have in Webb,” said UNCOVER co-investigator Gabriel Brammer of the Niels Bohr Institute’s Cosmic Dawn Center at the University of Copenhagen. “This is just the beginning of all the amazing Webb science to come.”

The imaging mosaics and catalog of sources on Pandora’s Cluster (Abell 2744) provided by the UNCOVER team combine publicly available Hubble data with Webb photometry from three early observation programs: JWST-GO-2561 , JWST-DD-ERS-1324 , and JWST-DD-2756 .

The James Webb Space Telescope is the world's premier space science observatory. Webb will solve mysteries in our solar system, look beyond to distant worlds around other stars, and probe 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 the Canadian Space Agency.




About This Release

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Media Contact:

Leah Ramsay
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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Tuesday, February 14, 2023

Astronomers confirm age of most distant galaxy with oxygen


The radio telescope array ALMA has pin-pointed the exact cosmic age of a distant JWST-identified galaxy, GHZ2/GLASS-z12, at 367 million years after the Big Bang. ALMA’s deep spectroscopic observations revealed a spectral emission line associated with ionized Oxygen near the galaxy, which has been shifted in its observed frequency due to the expansion of the Universe since the line was emitted. This observation confirms that the JWST is able to look out to record distances, and heralds a leap in our ability to understand the formation of the earliest galaxies in the Universe.Credit:NASA / ESA / CSA / T. Treu, UCLA / NAOJ / T. Bakx, Nagoya U.
Licence type:
Attribution (CC BY 4.0)

A new study led by a joint team at Nagoya University and the National Astronomical Observatory of Japan has measured the cosmic age of a very distant galaxy. The team used the ALMA radio telescope array to detect a radio signal that has been travelling for approximately 97% of the age of the Universe. This discovery confirms the existence of galaxies in the very early Universe found by the James Webb Space Telescope. The research is published in Monthly Notices of the Royal Astronomical Society.

The galaxy, named GHZ2/GLASS-z12, was initially identified in the JWST GLASS survey, a survey that observes the distant Universe and behind massive clusters of galaxies. These observations consist of several images using different broad-band colour filters, similar to the separate RGB colours in a camera. For distant galaxies, the light takes such a long time to reach us that the expansion of the Universe has shifted the colour of this light towards the red end of the visible light spectrum in the so-called redshift. The red colour of GHZ2/GLASS-z12 consequently helped researchers identify it as one of the most convincing candidates for a distant galaxy they observed.

So many bright distant galaxies were identified in the first few weeks of JWST observations that it challenged our basic understanding of the formation of the earliest galaxies. However, these red colours are only indicative of a distant galaxy, and could instead be a very dust-rich galaxy masquerading as a more distant object. Only direct observations of spectral lines – lines present in a galaxy’s light spectrum used to identify the elements present – can robustly confirm the true distances of these galaxies.

Immediately after the discovery of these early galaxy candidates, two early-career researchers at Nagoya University and the National Astronomical Observatory of Japan used the forty radio telescopes of the ALMA array in Chile to hunt for a spectral line to confirm the true ages of the galaxies.


The image of galaxy GHZ2/GLASS-z12 with the associated ALMA spectrum. ALMA’s deep spectroscopic observations revealed a spectral emission line associated with ionized Oxygen near the galaxy, which has been shifted in its observed frequency due to the expansion of the Universe since the line was emitted. Credit: NASA / ESA / CSA / T. Treu, UCLA / NAOJ / T. Bakx, Nagoya U.

ALMA pointed at GHZ2/GLASS-z12 to hunt for an emission line associated with oxygen at the expected frequency suggested by the JWST observations. Oxygen is a typically abundant element in distant galaxies due to its relatively short formation timescale, therefore the team chose to search for an oxygen emission line to increase chances of detection.

By combining the signal of each of its 12 metre telescopes, ALMA was able to detect the emission line close to the position of the galaxy. The observed redshift of the line indicates we see the galaxy as it was just 367 million years after the Big Bang.

“The first images of the James Webb Space Telescope revealed so many early galaxies, that we felt we had to test its results using the best observatory on Earth”, said lead author Tom Bakx of Nagoya University. “It was a very exciting time to be an observational astronomer, and we could track the status of the observations that will test the JWST results in real time.”

“We were initially concerned about the slight variation in position between the detected oxygen emission line and the galaxy seen by Webb”, author Tom Bakx notes, “but we performed detailed tests on the observations to confirm that this really is a robust detection, and it is very difficult to explain through any other interpretation.”

Co-lead author Jorge Zavala of the National Astronomical Observatory of Japan adds, “The bright line emission indicates that this galaxy has quickly enriched its gas reservoirs with elements heavier than hydrogen and helium. This gives us some clues about the formation and evolution of the first generation of stars and their lifetime. The small separation we see between the oxygen gas and the stars’ emission might also suggest that these early galaxies suffered from violent explosions that blew the gas away from the galaxy centre into the region surrounding the galaxy and even beyond.”

“These deep ALMA observations provide robust evidence of the existence of galaxies within the first few hundred million years after the Big Bang, and confirms the surprising results from the Webb observations. The work of JWST has only just begun, but we are already adjusting our models of how galaxies form in the early Universe to match these observations. The combined power of Webb and the radio telescope array ALMA give us the confidence to push our cosmic horizons ever closer to the dawn of the Universe.”




Media contacts:

Gurjeet Kahlon
Royal Astronomical Society
Mob: +44 (0)7802 877700

press@ras.ac.uk

Dr Robert Massey
Royal Astronomical Society
Mob: +44 (0)7802 877699

press@ras.ac.uk

Science contacts:

Dr Tom Bakx
Nagoya University

tjlcbakx@gmail.com

Dr Jorge Zavala
NAOJ ALMA Division

jorge.zavala@nao.ac.jp

Further information

The research appears inDeep ALMA redshift search of a z ∼ 12 GLASS-JWST galaxy candidate’, Bakx et al., published in Monthly Notices of the Royal Astronomical Society, in press.




Notes for editors:

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