Record-Breaking Cosmic Structure Discovered in Colossal Galaxy Cluster

This new composite image made with X-rays from NASA’s Chandra X-ray Observatory (blue and purple), radio data from the MeerKAT radio telescope (orange and yellow), and an optical image from PanSTARRS (red, green, and blue) shows PLCK G287.0+32.9. This massive galaxy cluster, located about 5 billion light-years from Earth, was first detected by astronomers in 2011. Credit: X-ray: NASA/CXC/CfA/K. Rajpurohit et al.; Optical: PanSTARRS; Radio: SARAO/MeerKAT; Image processing: NASA/CXC/SAO/N. Wolk. High Resolution Image

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A CfA astronomer and her team have imaged the largest known cloud of energetic particles surrounding a galaxy cluster, and raised new questions about what powers and re-energizes particles in the Universe over time.

Cambridge, MA - Astronomers have discovered the largest known cloud of energetic particles surrounding a galaxy cluster— spanning nearly 20 million light-years. The finding challenges long-standing theories about how particles stay energized over time. Instead of being powered by nearby galaxies, this vast region seems to be energized by giant shockwaves and turbulence moving through the hot gas between galaxies.

The results of the new study, led by scientists at the Center for Astrophysics | Harvard & Smithsonian (CfA), were presented today in a press conference at the 246th meeting of the American Astronomical Society (AAS).

Located five billion light-years from Earth, PLCK G287.0+32.9 is a massive galaxy cluster that has piqued the interest of astronomers since it was first detected in 2011. Earlier studies spotted two bright relics— giant shockwaves that lit up the cluster's edges. But they missed the vast, faint radio emission that fills the space between them. New radio images reveal that the entire cluster is wrapped in a faint radio glow, nearly 20 times the diameter of the Milky Way, suggesting that something much larger and more powerful is at work.

"We expected a bright pair of relics at the cluster's edges, which would have matched prior observations, but instead we found the whole cluster glowing in radio light," said lead author, Dr. Kamlesh Rajpurohit, a Smithsonian astronomer at the CfA. "A cloud of energetic particles this large has never been observed in this galaxy cluster or any other." The prior record holder, Abell 2255, spans roughly 16.3 million light-years.

Deep in the cluster's central region, the team detected a radio halo approximately 11.4 million light-years across, the first of its size seen at 2.4 GHz, a radio frequency where halos this large are usually not visible. The findings raise questions for the team because they provide strong evidence for the presence of cosmic ray electrons and magnetic fields stretched out to the periphery of clusters. However, it remains unclear how these electrons accelerated over such large distances.

"Very extended radio halos are mostly only visible at lower frequencies because the electrons that produce them have lost energy — they're old and have cooled over time," said Rajpurohit. "With the discovery of this enormous size halo we are now seeing radio emission extending all the way between the giant shocks and beyond, filling the entire cluster. That suggests something is actively accelerating, or re-accelerating the electrons, but none of the usual suspects apply. We think that giant shockwaves or turbulence could be responsible, but we need more theoretical models to find a definitive answer." The discovery provides researchers a new way to study cosmic magnetic fields— one of the major unanswered questions in astrophysics— that could help scientists understand how magnetic fields shape the Universe on the largest scales.

"We're starting to see the Universe in ways we never could before," said Rajpurohit. "And that means rethinking how energy and matter move through its largest structures." Observations with NASA's Chandra X-ray Observatory, operated by the Smithsonian Astrophysical Observatory, reveal a box-shaped structure, a comet-like tail, and several other distinct features in the cluster's hot gas, suggesting that the cluster is highly disturbed. Some of these X-ray features coincide with radio-detected structures, suggesting giant shocks and turbulence driven by mergers accelerating or re-accelerating electrons. In the center of the cluster, some of these features may be caused by a merger of two smaller galaxy clusters, or from outbursts produced by a supermassive black hole, or both.

Source: Harvard-Smithsonian Center for Astrophysics (CfA)/News Release

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Media Contact:

Amy C. Oliver
Public Affairs Officer
Center for Astrophysics | Harvard & Smithsonian
amy.oliver@cfa.harvard.edu

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Resources

K. Rajpurohit et al."Diffuse Radio Emission Spanning 6 Mpc in the Highly Disturbed Galaxy Cluster PLCK G287.0+32.9," pending submission

K. Rajpurohit et al. "Radial Profiles of Radio Halos in Massive Galaxy Clusters: Diffuse Giants Over 2 Mpc" submitted to ApJ, preprint is here

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About the Center for Astrophysics | Harvard & Smithsonian

The Center for Astrophysics | Harvard & Smithsonian is a collaboration between Harvard and the Smithsonian designed to ask—and ultimately answer—humanity's greatest unresolved questions about the nature of the universe. The Center for Astrophysics is headquartered in Cambridge, MA, with research facilities across the U.S. and around the world.

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Sloshing cold front detected in a massive galaxy cluster

RGB (tricolor) image of Abell 2566 obtained by proper combination of emission measured at 1.4 GHz with VLA

By analyzing the data from NASA's Chandra X-ray observatory, astronomers from India and South Africa have investigated a massive galaxy cluster known as Abell 2566. They detected sloshing cold fronts in the intracluster medium (ICM) of this cluster. The finding was reported in a research paper published May 17 on the preprint server arXiv.

Galaxy clusters contain up to thousands of galaxies bound together by gravity. They are the largest known gravitationally bound structures in the universe, and could serve as excellent laboratories for studying galaxy evolution and cosmology.

In general, the so-called cold fronts are sharp surface brightness discontinuities observed in X-ray images, where the drop of the surface brightness and gas density is accompanied by a jump in the gas temperature, with the denser region colder than the more rarefied region.

Now, a team of astronomers led by Sonali K. Kadam of the Swami Ramanand Teerth Marathwada University in India has identified such features in Abell 2566—a cool core galaxy cluster at a redshift of 0.08, with an estimated mass of about 217 trillion solar masses.

By analyzing Chandra images and archival radio data, Kadam's team found evidence of gas sloshing in the core of Abell 2566 along with a pair of cold fronts in its environment.

First of all, the collected images unveiled an unusual morphology of ICM distribution—in the form of spiral-shaped gas sloshing along with edges in the surface brightness distribution. Spectral analysis conducted by the astronomers then confirmed an association of these morphological discontinuities with the cold fronts.

"A detailed analysis of the sectorial brightness profiles along these edges confirm their origin due to sloshing of gas, referred to as the sloshing cold fronts," the researchers explained.

Furthermore, the observations identified an offset of about 22,200 light years between the brightest cluster galaxy (BCG) and the X-ray emission peak, as well as close association of the BCG with a neighboring system. The authors of the paper suppose that this offset might have yielded the sloshing structure in Abell 2566.

Based on the collected data, the astronomers assume that the observed features and complex morphology of plasma distribution in Abell 2566 share a common origin—as they may be due to a minor merger. The team noted that a sub-cluster may have disturbed the main cluster by displacing its gravitational potential well.

"Such a displacement further results in the formation of cold fronts, the concentrically shaped borders in the surface brightness produced by the core's gas as it moves around the potential well. These cold fronts further develop spiral patterns in the plasma distribution provided the sloshing direction is close to the plane of sky," the scientists concluded.

by Tomasz Nowakowski, Phys.org

Source: Phys.Org/Astronomy & Space

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More information: S. K. Kadam et al, Sloshing Cold Fronts in Galaxy Cluster Abell 2566, arXiv (2024). DOI: 10.48550/arxiv.2405.10475

Journal information: arXiv

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© 2024 Science X Network

Explore further

Two large cold fronts detected in the galaxy cluster Abell 3558

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Hubble Makes Surprising Find in the Early Universe

PR Image heic2010a

The Early Universe (artist’s impression)

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Galaxy Cluster MACSJ0416

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Videos

PR Video heic2010a

Hubblecast 118: How the first stars transformed the Universe

PR Video heic2010b

Hubble Probes the Early Universe (artist’s impression)

PR Video heic2010c

Animation of gravitational lensing (artist’s impression)

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New results from the NASA/ESA Hubble Space Telescope suggest the formation of the first stars and galaxies in the early Universe took place sooner than previously thought. A European team of astronomers have found no evidence of the first generation of stars, known as Population III stars, as far back as when the Universe was just 500 million years old.

The exploration of the very first galaxies remains a significant challenge in modern astronomy. We do not know when or how the first stars and galaxies in the Universe formed. These questions can be addressed with the Hubble Space Telescope through deep imaging observations. Hubble allows astronomers to view the Universe back to within 500 million years of the Big Bang. 

A team of European researchers, led by Rachana Bhatawdekar of the European Space Agency, set out to study the first generation of stars in the early Universe. Known as Population III stars [1] , these stars were forged from the primordial material that emerged from the Big Bang. Population III stars must have been made solely out of hydrogen, helium and lithium, the only elements that existed before processes in the cores of these stars could create heavier elements, such as oxygen, nitrogen, carbon and iron.

Bhatawdekar and her team probed the early Universe from about 500 million to 1 billion years after the Big Bang by studying the cluster MACSJ0416 and its parallel field with the Hubble Space Telescope (with supporting data from NASA’s Spitzer Space Telescope and the ground-based Very Large Telescope of the European Southern Observatory). "We found no evidence of these first-generation Population III stars in this cosmic time interval" said Bhatawdekar of the new results.

The result was achieved using the Hubble’s Space Telescope’s Wide Field Camera 3 and Advanced Camera for Surveys [2], as part of the Hubble Frontier Fields programme. This programme (which observed six distant galaxy clusters from 2012 to 2017) produced the deepest observations ever made of galaxy clusters and the  galaxies located behind them which were magnified by the gravitational lensing effect, thereby revealing galaxies 10 to 100 times fainter than any previously observed. The masses of foreground galaxy clusters are large enough to bend and magnify the light from the more distant objects behind them. This allows Hubble to use these cosmic magnifying glasses to study objects that are beyond its nominal operational capabilities. 

Bhatawdekar and her team developed a new technique that removes the light from the bright foreground galaxies that constitute these gravitational lenses. This allowed them to discover galaxies with lower masses than ever previously observed with Hubble, at a distance corresponding to when the Universe was less than a billion years old. At this point in cosmic time, the lack of evidence for exotic stellar populations and the identification of many low-mass galaxies supports the suggestion that these galaxies are the most likely candidates for the reionisation of the Universe. This period of reionisation in the early Universe is when the neutral intergalactic medium was ionised by the first stars and galaxies.

“These results have profound astrophysical consequences as they show that galaxies must have formed much earlier than we thought,” said Bhatawdekar. “This also strongly supports the idea that low-mass/faint galaxies in the early Universe are responsible for reionisation.” 

These results [3] also suggest that the earliest formation of stars and galaxies occurred much earlier than can be probed with the Hubble Space Telescope. This leaves an exciting area of further research for the upcoming NASA/ESA/CSA James Webb Space Telescope — to study the Universe’s earliest galaxies.

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Notes

[1] The name Population III arose because astronomers had already classified the stars of the Milky Way as Population I (stars like the Sun, which are rich in heavier elements) and Population II (older stars with a low heavy-element content, found in the Milky Way bulge and halo, and in globular star clusters).

[2] Owing to the expansion of the Universe, the light from the distant galaxies is shifted from ultraviolet and optical wavelengths into the infrared part of the electromagnetic spectrum. Hubble’s Wide Field Camera 3 is well equipped to probe this part of the spectrum. In addition, the telescope’s Advanced Camera for Surveys is optimised for visible/ light observations. 

[3] These results are based on a previous 2019 paper by Bhatawdekar et al., and a paper that will appear in an upcoming issue of the Monthly Notices of the Royal Astronomical Society (MNRAS). These results are also being presented at a press conference during the 236th meeting of American Astronomical Society.

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More Information

The Hubble Space Telescope is a project of international cooperation between ESA and NASA.

The European team of astronomers in this study consists of R. Bhatawdekar and C. J. Conselice.

Image credit: ESA/Hubble, M. Kornmesser.

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Links

• Images of Hubble 
• Space Scoop article
• Hubblesite release

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Contacts

Dr Rachana Bhatawdekar
European Space Agency / ESTEC
Noordwijk, The Netherlands
Email: Rachana.Bhatawdekar@esa.int

Bethany Downer
ESA/Hubble, Public Information Officer
Garching, Germany
Email: Bethany.Downer@partner.eso.org

Source: ESA/Hubble/News

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Largest Galaxy Proto-Supercluster Found

 PR Image eso1833a

The Hyperion Proto-Supercluster 

PR Image eso1833b

Comparison of the Hyperion Proto-Supercluster and a standard massive galaxy cluster

PR Image eso1833c

Wide-field view of the COSMOS field

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Videos

PR Video eso1833a

ESOcast 179 Light: Largest Galaxy Proto-Supercluster Found (4K UHD)

PR Video eso1833b

The Hyperion Proto-Supercluster

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Astronomers using ESO’s Very Large Telescope uncover a cosmic titan lurking in the early Universe

An international team of astronomers using the VIMOS instrument of ESO’s Very Large Telescope have uncovered a titanic structure in the early Universe. This galaxy proto-supercluster — which they nickname Hyperion — was unveiled by new measurements and a complex examination of archive data. This is the largest and most massive structure yet found at such a remote time and distance — merely 2 billion years after the Big Bang.

A team of astronomers, led by Olga Cucciati of Istituto Nazionale di Astrofisica (INAF) Bologna, have used the VIMOS instrument on ESO’s Very Large Telescope (VLT) to identify a gigantic proto-supercluster of galaxies forming in the early Universe, just 2.3 billion years after the Big Bang. This structure, which the researchers nicknamed Hyperion, is the largest and most massive structure to be found so early in the formation of the Universe [1]. The enormous mass of the proto-supercluster is calculated to be more than one million billion times that of the Sun. This titanic mass is similar to that of the largest structures observed in the Universe today, but finding such a massive object in the early Universe surprised astronomers.

“This is the first time that such a large structure has been identified at such a high redshift, just over 2 billion years after the Big Bang,” explained the first author of the discovery paper, Olga Cucciati [2]. “Normally these kinds of structures are known at lower redshifts, which means when the Universe has had much more time to evolve and construct such huge things. It was a surprise to see something this evolved when the Universe was relatively young!”

Located in the COSMOS field in the constellation of Sextans (The Sextant), Hyperion was identified by analysing the vast amount of data obtained from the VIMOS Ultra-deep Survey led by Olivier Le Fèvre (Aix-Marseille Université, CNRS, CNES). The VIMOS Ultra-Deep Survey provides an unprecedented 3D map of the distribution of over 10 000 galaxies in the distant Universe.

The team found that Hyperion has a very complex structure, containing at least 7 high-density regions connected by filaments of galaxies, and its size is comparable to nearby superclusters, though it has a very different structure.

“Superclusters closer to Earth tend to a much more concentrated distribution of mass with clear structural features,” explains Brian Lemaux, an astronomer from University of California, Davis and LAM, and a co-leader of the team behind this result. “But in Hyperion, the mass is distributed much more uniformly in a series of connected blobs, populated by loose associations of galaxies.”

This contrast is most likely due to the fact that nearby superclusters have had billions of years for gravity to gather matter together into denser regions — a process that has been acting for far less time in the much younger Hyperion.

Given its size so early in the history of the Universe, Hyperion is expected to evolve into something similar to the immense structures in the local Universe such as the superclusters making up the Sloan Great Wall or the Virgo Supercluster that contains our own galaxy, the Milky Way. “Understanding Hyperion and how it compares to similar recent structures can give insights into how the Universe developed in the past and will evolve into the future, and allows us the opportunity to challenge some models of supercluster formation,” concluded Cucciati. “Unearthing this cosmic titan helps uncover the history of these large-scale structures.”

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Notes

[1] The moniker Hyperion was chosen after a Titan from Greek mythology, due to the immense size and mass of the proto-supercluster. The inspiration for this mythological nomenclature comes from a previously discovered proto-cluster found within Hyperion and named Colossus. The individual areas of high density in Hyperion have been assigned mythological names, such as Theia, Eos, Selene and Helios, the latter being depicted in the ancient statue of the Colossus of Rhodes.

The titanic mass of Hyperion, one million billion times that of the Sun, is 10¹⁵ solar masses in scientific notation.

[2] Light reaching Earth from extremely distant galaxies took a long time to travel, giving us a window into the past when the Universe was much younger. This wavelength of this light has been stretched by the expansion of the Universe over its journey, an effect known as cosmological redshift. More distant, older objects have a correspondingly larger redshift, leading astronomers to often use redshift and age interchangeably. Hyperion’s redshift of 2.45 means that astronomers observed the proto-supercluster as it was 2.3 billion years after the Big Bang.

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More Information

This research is published in the paper “The progeny of a Cosmic Titan: a massive multi-component proto-supercluster in formation at z=2.45 in VUDS”, which will appear in the journal Astronomy & Astrophysics.

The team behind this result was composed of O. Cucciati (INAF-OAS Bologna, Italy), B. C. Lemaux (University of California, Davis, USA and LAM - Aix Marseille Université, CNRS, CNES, France), G. Zamorani (INAF-OAS Bologna, Italy), O.Le Fèvre (LAM - Aix Marseille Université, CNRS, CNES, France), L. A. M. Tasca (LAM - Aix Marseille Université, CNRS, CNES, France), N. P. Hathi (Space Telescope Science Institute, Baltimore, USA), K-G. Lee (Kavli IPMU (WPI), The University of Tokyo, Japan, & Lawrence Berkeley National Laboratory, USA), S. Bardelli (INAF-OAS Bologna, Italy), P. Cassata (University of Padova, Italy), B. Garilli (INAF–IASF Milano, Italy), V. Le Brun (LAM - Aix Marseille Université, CNRS, CNES, France), D. Maccagni (INAF–IASF Milano, Italy), L. Pentericci (INAF–Osservatorio Astronomico di Roma, Italy), R. Thomas (European Southern Observatory, Vitacura, Chile), E. Vanzella (INAF-OAS Bologna, Italy), E. Zucca (INAF-OAS Bologna, Italy), L. M. Lubin (University of California, Davis, USA), R. Amorin (Kavli Institute for Cosmology & Cavendish Laboratory, University of Cambridge, UK), L. P. Cassarà (INAF–IASF Milano, Italy), A. Cimatti (University of Bologna & INAF-OAS Bologna, Italy), M. Talia (University of Bologna, Italy), D. Vergani (INAF-OAS Bologna, Italy), A. Koekemoer (Space Telescope Science Institute, Baltimore, USA), J. Pforr (ESA ESTEC, the Netherlands), and M. Salvato (Max-Planck-Institut für Extraterrestrische Physik, Garching bei München, Germany).

ESO is the foremost intergovernmental astronomy organisation in Europe and the world’s most productive ground-based astronomical observatory by far. It has 16 Member States: Austria, Belgium, the Czech Republic, Denmark, France, Finland, Germany, 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 carries out an ambitious programme focused on the design, construction and operation of powerful ground-based observing facilities enabling astronomers to make important scientific discoveries. ESO also plays a leading role in promoting and organising cooperation in astronomical research. ESO operates three unique world-class observing sites in Chile: La Silla, Paranal and Chajnantor. At Paranal, ESO operates the Very Large Telescope and its world-leading Very Large Telescope Interferometer as well as two survey telescopes, VISTA working in the infrared and the visible-light VLT Survey Telescope. ESO is also a major partner in two facilities on Chajnantor, APEX and ALMA, the largest astronomical project in existence. And on Cerro Armazones, close to Paranal, ESO is building the 39-metre Extremely Large Telescope, the ELT, which will become “the world’s biggest eye on the sky”.

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Links

• Research paper
• The VIMOS Ultra Deep Survey description
• Images of the VLT

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Contacts

Olga Cucciati
INAF Fellow – Osservatorio di Astrofisica e Scienza dello Spazio di Bologna
Bologna, Italy
Email: olga.cucciati@inaf.it

Calum Turner
ESO Public Information Officer
Garching bei München, Germany
Tel: +49 89 3200 6670
Email: pio@eso.org

Source: ESO/News

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A colossal cluster

PLCK_G308.3-20.2

Credit: ESA/Hubble & NASA, RELICS

This NASA/ESA Hubble Space Telescope image shows a massive galaxy cluster glowing brightly in the darkness. Despite its beauty, this cluster bears the distinctly unpoetic name of PLCK_G308.3-20.2. 

Galaxy clusters can contain thousands of galaxies all held together by the glue of gravity. At one point in time they were believed to be the largest structures in the Universe — until they were usurped in the 1980s by the discovery of superclusters, which typically contain dozens of galaxy clusters and groups and span hundreds of millions of light-years. However, clusters do have one thing to cling on to; superclusters are not held together by gravity, so galaxy clusters still retain the title of the biggest structures in the Universe bound by gravity.

One of the most interesting features of galaxy clusters is the stuff that permeates the space between the constituent galaxies: the intracluster medium (ICM). High temperatures are created in these spaces by smaller structures forming within the cluster. This results in the ICM being made up of plasma — ordinary matter in a superheated state. Most luminous matter in the cluster resides in the ICM, which is very luminous X-rays. However, the majority of the mass in a galaxy cluster exists in the form of non-luminous dark matter. Unlike plasma, dark matter is not made from ordinary matter such as protons, neutrons and electrons. It is a hypothesised substance thought to make up 80 % of the Universe’s mass, yet it has never been directly observed.

This image was taken by Hubble’s Advanced Camera for Surveys and Wide-Field Camera 3 as part of an observing programme called RELICS (Reionization Lensing Cluster Survey). RELICS imaged 41 massive galaxy clusters with the aim of finding the brightest distant galaxies for the forthcoming NASA/ESA/CSA James Webb Space Telescope (JWST) to study.

Source: ESA /Hubble/Potw

Primordial Galaxy Discovered, First of Its Kind

Graphic illustration of how MACS1423-z7p64 was detected via gravitational lensing with NASA’s Hubble Space Telescope and confirmed by W. M. Keck Observatory’s MOSFIRE. Credit:  NASA/W.M. Keck Observatory/A. Hoag/M. Bradac

UC Davis Associate Physics Professor, Dr. Marusa Bradac, and UC Davis Physics Graduate Student, Austin Hoag, at the W. M. Keck Observatory. Credit: A. Hoag/M. Bradac

Maunakea, Hawaii– Seven years of meticulous observing have resulted in a cosmic discovery that comes from an era dating back 13.1 billion years, giving scientists a detailed glimpse of what may have happened just after the Big Bang.

Using the world-class W. M. Keck Observatory on Maunakea, Hawaii, an international team of astronomers from the United States, Australia, and Europe has confirmed the existence of one of the most distant galaxies in the universe.

To characterize the faint galaxy, the discovery team, led by Austin Hoag, a University of California, Davis physics graduate student, used MOSFIRE, the most in-demand instrument on the 10-meter Keck I telescope.

What makes this galaxy extraordinary is that it is ordinary. It is thought to be a common galaxy at that distance and age of the universe. However, such galaxies would normally be too faint to detect. The astronomers used a method called gravitational lensing to magnify the galaxy so they could study it.

“Most objects that we’ve seen at that distance are extremely bright, and probably rare compared to other galaxies,” said Hoag. “We think this galaxy is much more representative of other galaxies of its time.”

The results publish today in Nature Astronomy, with Hoag as the lead author on the paper.

“I’m like a proud academic mother,” said Marusa Bradac, associate physics professor at UC Davis. “It is a wonderful opportunity for graduate students to use the world’s best facilities to discover first galaxies and get their research published in Nature Astronomy.”

Named MACS1423-z7p64, the galaxy is at a redshift of 7.6, meaning its light came from when the universe was approximately 700 million years old.

“This is an awesome discovery in that it is the faintest galaxy at that redshift ever detected. It is very challenging to find an object at the very edges of the universe. In order to detect this galaxy, its light had to be lensed twice - once by a massive galaxy cluster, and a second time by the Keck Observatory telescope,” said Keck Observatory instrument program manager Marc Kassis who, along with fellow support astronomers Luca Rizzi and Carlos Alvarez, helped support Hoag and his team.

To find such faint, distant objects, the discovery team took advantage of a method called gravitational lensing. As light of the distant object passes by a massive object such as a galaxy cluster in the foreground, it gets bent by gravity, just as light gets bent passing through a lens. When the foreground object is massive enough, it will magnify the object behind it. MACS1423-z7p64 just happened to fall into the “sweet spot” behind a giant galaxy cluster that magnified its brightness tenfold and made it first visible to the team using the Hubble Space Telescope. They were then able to confirm its distance by analyzing its spectrum using Keck Observatory’s MOSFIRE.

Even though MACS1423-z7p64 is strongly magnified, the discovery has been extremely challenging and it required combining the initial data taken by UC Davis researchers in 2015 with those from a second night of Keck observations from Australian colleagues at the University of Melbourne in 2016.

“This detection of Lyman-α emission from the galaxy thus highlights the strength of collaborative research projects,” said Michele Trenti from the University of Melbourne, principal investigator of the Australian observations. “This is yet another discovery that puts UC Davis, UCLA, and University of Melbourne on the map as among the top astronomy centers in their nations, and the reason for that is due to our access to the Keck telescopes,” said Bradac. “For this kind of research, every meter of telescope aperture counts, and without the low humidity on Maunakea, we would not have been able to discover this.”

What’s Next

The discovery team plans to continue surveying candidate galaxies with the Hubble and Keck telescopes. Hoag says the upcoming launch of the James Webb Space Telescope (JWST), set for 2018, opens up new possibilities. The team is currently planning observations for the Webb telescope, which is bigger than Hubble and will allow astronomers to look at even more distant parts of the universe. As such, the very distant galaxies discovered by Keck Observatory in collaboration with the Hubble Space Telescope are precious candidates for further investigation by JWST.

“We will truly witness the birth of the first galaxies, which will allow us to answer the longstanding question of, ‘Where did we come from?’” Bradac said.

Ultradistant galaxies are of interest to scientists because they date back to a period known as the “Epoch of Reionization” – about a billion years after the Big Bang when the earliest stars and galaxies began to emit visible light into the universe for the very first time. Having the ability to study this light could give researchers the data they need to piece together the first chapters of our cosmic history and trace the origin of celestial objects we see today, including stars like our own Sun.

Media Contact:

Mari-Ela Chock, Communications Officer
W. M. Keck Observatory
(808) 554-0567
mchock@keck.hawaii.edu

Science Contact:

Andy Fell, Associate Director, Research Communications
University of California, Davis
(530) 752-4533
ahfell@ucdavis.edu

Source: W.M. Keck Observatory

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About MOSFIRE

W. M. Keck Observatory’s instrument, the Multi-Object Spectrograph for Infrared Exploration (MOSFIRE), gathers spectra from objects spanning a variety of distances, environments and physical conditions. What makes this large, vacuum-cryogenic instrument unique is its ability to select up to 46 individual objects in the field of view and then record the infrared spectrum of all 46 objects simultaneously. When a new field is selected, a robotic mechanism inside the vacuum chamber reconfigures the distribution of tiny slits in the focal plane in under six minutes. Eight years in the making with First Light in 2012, MOSFIRE's early performance results range from the discovery of ultra-cool, nearby substellar mass objects, to the detection of oxygen in young galaxies only two billion years after the Big Bang.

Other Authors

• UC Davis: Kuang-Han Huang, Brian Lemaux, and Julie He
• University of Melbourne, Australia: Michele Trenti and Stephanie Bernard
• University of California, Los Angeles (UCLA): Tommaso Treu, Louis E. Abramson, Charlotte Mason, and Takahiro Morishita
• Leibniz-Institut für Astrophysik Potsdam, Germany: Kasper Schmidt
• INAF Osservatorio Astronomico di Roma, Italy: Laura Pentericci
• Argelander-Institut für Astronomie, Bonn, Germany: Tim Schrabback

About W. M. Keck Observatory

The W. M. Keck Observatory operates the largest, most scientifically productive telescopes on Earth. The two, 10-meter optical/infrared telescopes on the summit of Maunakea on the Island of Hawaii feature a suite of advanced instruments including imagers, multi-object spectrographs, high-resolution spectrographs, an integral-field spectrometer and world-leading laser guide star adaptive optics systems. The Observatory is a private 501(c) 3 non-profit organization and a scientific partnership of the California Institute of Technology, the University of California, and NASA.

A transformation in Virgo

NGC 4388

Credit: ESA/Hubble & NASA

The constellation of Virgo (The Virgin) is especially rich in galaxies, due in part to the presence of a massive and gravitationally-bound collection of over 1300 galaxies called the Virgo Cluster. One particular member of this cosmic community, NGC 4388, is captured in this image, as seen by the NASA/ESA Hubble Space Telescope’s Wide Field Camera 3 (WFC3). 

Located some 60 million light-years away, NGC 4388 is experiencing some of the less desirable effects that come with belonging to such a massive galaxy cluster. It is undergoing a transformation, and has taken on a somewhat confused identity. 

While the galaxy’s outskirts appear smooth and featureless, a classic feature of an elliptical galaxy, its centre displays remarkable dust lanes constrained within two symmetric spiral arms, which emerge from the galaxy’s glowing core — one of the obvious features of a spiral galaxy. Within the arms, speckles of bright blue mark the locations of young stars, indicating that NGC 4388 has hosted recent bursts of star formation. 

Despite the mixed messages, NGC 4388 is classified as a spiral galaxy. Its unusual combination of features are thought to have been caused by interactions between NGC 4388 and the Virgo Cluster.

Gravitational interactions — from glancing blows to head-on collisions, tidal influencing, mergers, and galactic cannibalism — can be devastating to galaxies. While some may be lucky enough to simply suffer a distorted spiral arm or newly-triggered wave of star formation, others see their structure and contents completely and irrevocably altered.

Source: ESA/Hubble/images

Cosmic Neighbors Inhibit Star Formation, Even in the Early-Universe

Massive galaxy cluster MACS J0416 seen in X-rays (blue), visible light (red, green, and blue), and radio light (pink). 
Credit: NASA/CXC/SAO/G.Ogrean/STScI/NRAO/AUI/NSF

Color images of the central regions of z > 1.35 SpARCS clusters. 
Cluster members are marked with white squares. 
Credit: Nantais, et al.

MAUNAKEA, Hawaii — The international University of California, Riverside-led SpARCS collaboration has discovered four of the most distant clusters of galaxies ever found, as they appeared when the Universe was only four billion years old. Clusters are rare regions of the Universe consisting of hundreds of galaxies containing trillions of stars, as well as hot gas and mysterious Dark Matter. Spectroscopic observations from the W. M. Keck Observatory on Maunakea, Hawaii and the Very Large Telescope in Chile confirmed the four candidates to be massive clusters. This sample is now providing the best measurement yet of when and how fast galaxy clusters stop forming stars in the early Universe.

“We looked at how the properties of galaxies in these clusters differed from galaxies found in more typical environments with fewer close neighbors,” said lead author Julie Nantais, an assistant professor at the Andres Bello University in Chile. “It has long been known that when a galaxy falls into a cluster, interactions with other cluster galaxies and with hot gas accelerate the shut off of its star formation relative to that of a similar galaxy in the field, in a process known as environmental quenching. The SpARCS team have developed new techniques using Spitzer Space Telescope infrared observations to identify hundreds of previously-undiscovered clusters of galaxies in the distant Universe.”

As anticipated, the team did indeed find that many more galaxies in the clusters had stopped forming stars compared to galaxies of the same mass in the field. Gillian Wilson, professor of physics and astronomy at UC Riverside, added, “Fascinatingly, however, the study found that the percentage of galaxies which had stopped forming stars in those young, distant clusters, was much lower than the percentage found in much older, nearby clusters. While it had been fully expected that the percentage of cluster galaxies which had stopped forming stars would increase as the Universe aged, this latest work quantifies the effect.”

The paper concludes that about 30 percent of the galaxies which would normally be forming stars have been quenched in the distant clusters, compared to the much higher value of about 50 percent found in nearby clusters.

Several possible physical processes could be responsible for causing environmental quenching. For example, the hot, harsh cluster environment might prevent the galaxy from continuing to accrete cold gas and form new stars; a process astronomers have named “starvation”. Alternatively, the quenching could be caused by interactions with other galaxies in the cluster. These galaxies might “harass” (undergo frequent, high speed, gravitationally-disturbing encounters), tidally strip (pull material from a smaller galaxy to a larger one) or merge (two or more galaxies joining together) with the first galaxy to stop its star formation.

While the current study does not answer the question of which process is primarily responsible, it is nonetheless hugely important because it provides the most accurate measurement yet of how much environmental quenching has occurred in the early Universe. Moreover, the study provides an all-important early-Universe benchmark by which to judge upcoming predictions from competing computational numerical simulations which make different assumptions about the relative importance of the many different environmental quenching processes which have been suggested, and the timescales upon which they operate.

The W. M. Keck Observatory findings were obtained as the result of a collaboration amongst UC faculty members Gillian Wilson (UCR) and Michael Cooper (UCI), and graduate students Andrew DeGroot (UCR) and Ryan Foltz (UCR). Other authors involved in the study are Remco van der Burg (Université Paris Diderot), Chris Lidman (Australian Astronomical Observatory), Ricardo Demarco (WUniversidad de Concepción, Chile), Allison Noble (University of Toronto, Canada) and Adam Muzzin (University of Cambridge).

The W. M. Keck Observatory operates the largest, most scientifically productive telescopes on Earth. The two, 10-meter optical/infrared telescopes near the summit of Maunakea on the Island of Hawaii feature a suite of advanced instruments including imagers, multi-object spectrographs, high-resolution spectrographs, integral-field spectrographs and world-leading laser guide star adaptive optics systems.

MOSFIRE (Multi-Object Spectrograph for Infrared Exploration) is a highly-efficient instrument that can take images or up to 46 simultaneous spectra. Using a sensitive state-of-the-art detector and electronics system, MOSFIRE obtains observations fainter than any other near infrared spectrograph. MOSFIRE is an excellent tool for studying complex star or galaxy fields, including distant galaxies in the early Universe, as well as star clusters in our own Galaxy. MOSFIRE was made possible by funding provided by the National Science Foundation and astronomy benefactors Gordon and Betty Moore.

Keck Observatory is a private 501(c) 3 non-profit organization and a scientific partnership of the California Institute of Technology, the University of California and NASA.

Media Contact:

Steve Jefferson
W. M. Keck Observatory
(808) 881-3827
sjefferson@keck.hawaii.edu

Source:  W.M. Keck Observatory

NASA Telescopes Find Galaxy Cluster with Vibrant Heart

Credit: NASA, ESA, STScI, JPL-Caltech, and T. Webb (McGill University)

Release Images

A massive cluster of galaxies, called SpARCS1049+56, can be seen in this two-panel, multi-wavelength view from NASA's Hubble and Spitzer space telescopes. At the middle of the picture is the largest, central member of the family of galaxies (upper right red dot of central pair). Unlike other central galaxies in clusters, this one is bursting with the birth of new stars.

Scientists say this star birth was triggered by a collision between a smaller galaxy and the giant, central galaxy. The smaller galaxy's wispy, shredded parts, called a tidal tail, can be seen coming out below the larger galaxy. Throughout this region are features called "beads on a string," which are areas where gas has clumped to form new stars.

This type of "feeding" mechanism for galaxy clusters — where gas from the merging of galaxies is converted to new stars — is rare.

The Hubble data in this image show infrared light with a wavelength of 1 micron in blue and 1.6 microns in green. The Spitzer data show infrared light of 3.6 microns in red.


Astronomers have discovered a rare beast of a galaxy cluster whose heart is bursting with new stars. The unexpected find, made with the help of NASA's Spitzer and Hubble space telescopes, suggests that behemoth galaxies at the cores of these massive clusters can grow significantly by feeding off gas stolen from other galaxies.

"Usually, the stars at the centers of galaxy clusters are old and dead, essentially fossils," said Tracy Webb of McGill University, Montreal, Canada, lead author of a new paper on the findings published in the Aug. 20 issue of The Astrophysical Journal. "But we think the giant galaxy at the center of this cluster is furiously making new stars after merging with a smaller galaxy."

Galaxy clusters are vast families of galaxies bound and grouped by the ties of gravity. Our own Milky Way resides in a small galaxy group, called the Local Group, which itself is on the periphery of the vast Laniakea supercluster of 100,000 galaxies. (Laniakea is Hawaiian for "immeasurable heaven.")

The cluster in the new study, referred to by astronomers as SpARCS1049+56, has at least 27 galaxy members, and a combined mass equal to nearly 400 trillion suns. It is located 9.8 billion light-years away in the Ursa Major constellation. The object was initially discovered using Spitzer and the Canada-France-Hawaii Telescope, located on Mauna Kea in Hawaii, and confirmed using the W.M. Keck Observatory, also on Mauna Kea.

What makes this cluster unique is its luminous heart of new stars. At the core of most massive galaxy clusters lies one hulking galaxy that usually doesn't produce new stars very quickly. The galaxy dominating the cluster SpARCS1049+56 is rapidly spitting out an enormous number of stars — about 860 new ones a year. For reference, our Milky Way makes only about one to two stars per year.

"With Spitzer's infrared camera, we can actually see the ferocious heat from all these hot young stars," said co-author Jason Surace from NASA's Spitzer Science Center at the California Institute of Technology in Pasadena, California. Spitzer detects infrared light, so it can see the warm glow of hidden, dusty regions where stars form.

Follow-up studies with Hubble in visible light helped confirm the source of the fuel, or gas, for the new stars. 

A smaller galaxy seems to have recently merged with the monster galaxy in the middle of the cluster, lending its gas to the larger galaxy and igniting a fury of new stars.

"Hubble found a train wreck of a merger at the center of this galaxy," said Webb.

Hubble specifically detected features in the smaller, merging galaxy called "beads on a string," which are pockets of gas that condense where new stars are forming. Beads on a string are telltale signs of collisions between gas-rich galaxies, a phenomenon known to astronomers as wet mergers, where "wet" refers to the presence of gas. In these smash-ups, the gas is quickly converted to new stars.

Dry mergers, by contrast, occur when galaxies with little gas collide and no new stars are formed. Typically, galaxies at the centers of clusters grow in mass through dry mergers at their core, or by siphoning gas into their centers.

The new discovery is one of the first known cases of a wet merger at the core of a distant galaxy cluster. Hubble previously discovered another, closer galaxy cluster containing a wet merger, but it wasn't forming stars as vigorously.

The researchers are planning more studies to find out how common galaxy clusters like SpARCS1049+56 are. The cluster may be an outlier — or it may represent an early time in our universe when gobbling up gas-rich galaxies was the norm.


Contact

Whitney Clavin
Jet Propulsion Laboratory, Pasadena, California
818-354-4673
whitney.clavin@jpl.nasa.gov

Ray Villard
Space Telescope Science Institute, Baltimore, Maryland
410-338-4514
villard@stsci.edu

Felicia Chou
NASA Headquarters, Washington, D.C.
202-358-0257
felicia.chou@nasa.gov

Source: HubbleSite

Cosmic Bumps on Cosmic Ripples

Abell 1689, one of the most massive galaxy clusters known. The hot gas in this and other galaxy clusters distort the shape of the cosmic microwave background radiation (the "SZ Effect"), and sensitive new results on these distortions from the South Pole Telescope confirm and refine previous conclusions while identifying some puzzling discrepancies. Credit: NASA, Benitez, Broadhurst, Ford, Clampin, Hartig, Illingworth, and the ACS Science Team and ESA

In 1969, the astrophysicists Rashid Sunyaev and Yakov Zel'dovich realized that the then recently discovered cosmic microwave background radiation (CMBR) would be distorted by hot cosmic gas. Hot electrons in the intergalactic medium preferentially scatter the light in one direction, causing a change in the brightness of the CMBR towards clusters of galaxies where electrons should be abundant. They showed that the effect would reveal the large-scale structure of the universe, the nature of the CMBR, cosmological parameters like the Hubble constant, and physical conditions in galaxy clusters.

The effect, now known as the effect (SZSunyaev-Zel'dovich E), was first spotted in 1978 after much searching. Both space- and ground-based instruments, including the Planck satellite, the South Pole Telescope (SPT), and others have released new catalogs of galaxy clusters selected using the SZE. CfA astronomers Matt Ashby, Matt Bayliss, Richard Foley, Christine Jones, Steve Murray, Brian Stalder, Tony Stark, and Alexey Vikhlinin were part of a large team that used the SPT to examine the SZE signatures of forty-six X-ray selected groups and clusters of galaxies. The X-ray observations are some of the most sensitive ever used to search for clusters; the most distant of the galaxy clusters detected to date from a cosmic epoch six billion years after the big bang.

The team reports generally very good agreement between the cosmological parameters they measure and those reported by other means, in particular the latest results from the Planck satellite study of the CMBR. However the agreement is not perfect: the team reports an unexpectedly weak SZE signal for less massive galaxy clusters. Although they did identify and measure several potential sources of contamination, the discrepancy is not easily explained away. They suggest one possibility: dust within the clusters is reducing the SZE signal. For now, the reason remains unknown; this mystery will be addressed in subsequent, deeper, more sensitive SZE observations planned for the SPT.

Reference(s):

"Analysis of Sunyaev–Zel'dovich Effect Mass–Observable Relations Using South Pole Telescope Observations of an X-ray Selected Sample of Low-Mass Galaxy Clusters and Groups," J. Liu et al., MNRAS, 448, 2085, 2015

Source: Smithsonian Astrophysical Observatory

Hubble Sees 'Ghost Light' From Dead GalaxiesGalaxy Cluster Abell 2744

Galaxy Cluster Abell 2744

Credit: NASA, ESA, M. Montes (IAC), and J. Lotz, M. Mountain, A. Koekemoer, and the HFF Team (STScI).  

Release images

NASA's Hubble Space Telescope has picked up the faint, ghostly glow of stars ejected from ancient galaxies that were gravitationally ripped apart several billion years ago. The mayhem happened 4 billion light-years away, inside an immense collection of nearly 500 galaxies nicknamed "Pandora's Cluster," also known as Abell 2744. The scattered stars are no longer bound to any one galaxy, and drift freely between galaxies in the cluster.

By observing the light from the orphaned stars, Hubble astronomers have assembled forensic evidence that suggests as many as six galaxies were torn to pieces inside the cluster over a stretch of 6 billion years. 

Computer modeling of the gravitational dynamics among galaxies in a cluster suggest that galaxies as big as our Milky Way are the likely candidates as the source of the stars. The doomed galaxies would have been pulled apart like taffy if they plunged through the center of the galaxy cluster where gravitational tidal forces are strongest. Astronomers have long hypothesized that the light from scattered stars should be detectable after such galaxies are disassembled. However, the predicted "intracluster" glow of stars is very faint and was therefore a challenge to identify.

"The Hubble data revealing the ghost light are important steps forward in understanding the evolution of galaxy clusters," said Ignacio Trujillo of the Instituto de Astrofísica de Canarias (IAC), La Laguna, Tenerife, Spain, one of the researchers involved in this study of Abell 2744. "It is also amazingly beautiful in that we found the telltale glow by utilizing Hubble's unique capabilities."

"The results are in good agreement with what has been predicted to happen inside massive galaxy clusters," added Mireia Montes of the IAC, lead author of the paper published in the Oct. 1 issue of The Astrophysical Journal.

The team estimates that the combined light of about 200 billion outcast stars contributes approximately 10 percent of the cluster's brightness.

Because these extremely faint stars are brightest at near-infrared wavelengths of light, the team emphasized that this type of observation could only be accomplished with Hubble's infrared sensitivity to extraordinarily dim light.

Hubble measurements determined that the phantom stars are rich in heavier elements like oxygen, carbon, and nitrogen. This means the scattered stars must be second- or third-generation stars that were enriched with the elements forged in the hearts of the universe's first-generation stars. Spiral galaxies — like the ones believed to be torn apart — can sustain ongoing star formation that creates chemically enriched stars.

With the mass of 4 trillion suns, Abell 2744 is a target in the Frontier Fields program. This ambitious three-year effort teams Hubble and NASA's other Great Observatories to look at select massive galaxy clusters to help astronomers probe the remote universe. Galaxy clusters are so massive that their gravity deflects light passing through them, magnifying, brightening, and distorting light in a phenomenon called gravitational lensing. Astronomers exploit this property of space to use the clusters as a zoom lens to magnify the images of far-more-distant galaxies that otherwise would be too faint to be seen.

Montes' team used the Hubble data to probe the environment of the foreground cluster itself. There are five other Frontier Fields clusters in the program, and the team plans to look for the eerie "ghost light" in these clusters, too.

CONTACTS

Felicia Chou
NASA Headquarters, Washington, D.C.
202-358-0257
felicia.chou@nasa.gov

Ray Villard
Space Telescope Science Institute, Baltimore, Md.
410-338-4514
villard@stsci.edu

Mireia Montes
Instituto de Astrofísica de Canarias, La Laguna, Tenerife, Spain
mireia.montes.quiles@gmail.com

Source: HubbleSite

New mass map of a distant galaxy cluster is the most precise yet

PR Image heic1416a

Colour image of galaxy cluster MCS J0416.1–2403

PR Image heic1416b

Colour image of galaxy cluster MCS J0416.1–2403, annotated

PR Image heic1416c

Mass map of galaxy cluster MCS J0416.1–2403 using strong and weak lensing

Stunning new observations from Frontier Fields

Astronomers using the NASA/ESA Hubble Space Telescope have mapped the mass within a galaxy cluster more precisely than ever before. Created using observations from Hubble's Frontier Fields observing programme, the map shows the amount and distribution of mass within MCS J0416.1–2403, a massive galaxy cluster found to be 160 trillion times the mass of the Sun. The detail in this mass map was made possible thanks to the unprecedented depth of data provided by new Hubble observations, and the cosmic phenomenon known as strong gravitational lensing.

Measuring the amount and distribution of mass within distant objects in the Universe can be very difficult. A trick often used by astronomers is to explore the contents of large clusters of galaxies by studying the gravitational effects they have on the light from very distant objects beyond them. This is one of the main goals of Hubble's Frontier Fields, an ambitious observing programme scanning six different galaxy clusters — including MCS J0416.1–2403, the cluster shown in this stunning new image [1].

Large clumps of mass in the Universe warp and distort the space-time around them. Acting like lenses, they appear to magnify and bend light that travels through them from more distant objects [2].

Despite their large masses, the effect of galaxy clusters on their surroundings is usually quite minimal. For the most part they cause what is known as weak lensing, making even more distant sources appear as only slightly more elliptical or smeared across the sky. However, when the cluster is large and dense enough and the alignment of cluster and distant object is just right, the effects can be more dramatic. The images of normal galaxies can be transformed into rings and sweeping arcs of light, even appearing several times within the same image. This effect is known as strong lensing, and it is this phenomenon, seen around the six galaxy clusters targeted by the Frontier Fields programme, that has been used to map the mass distribution of MCS J0416.1–2403, using the new Hubble data.

"The depth of the data lets us see very faint objects and has allowed us to identify more strongly lensed galaxies than ever before," explains Mathilde Jauzac of Durham University, UK, and Astrophysics & Cosmology Research Unit, South Africa, lead author of the new Frontier Fields paper. "Even though strong lensing magnifies the background galaxies they are still very far away and very faint. The depth of these data means that we can identify incredibly distant background galaxies. We now know of more than four times as many strongly lensed galaxies in the cluster than we did before."

Using Hubble's Advanced Camera for Surveys, the astronomers identified 51 new multiply imaged galaxies around the cluster, quadrupling the number found in previous surveys and bringing the grand total of lensed galaxies to 68. Because these galaxies are seen several times this equates to almost 200 individual strongly lensed images which can be seen across the frame. This effect has allowed Jauzac and her colleagues to calculate the distribution of visible and dark matter in the cluster and produce a highly constrained map of its mass [3].

"Although we’ve known how to map the mass of a cluster using strong lensing for more than twenty years, it’s taken a long time to get telescopes that can make sufficiently deep and sharp observations, and for our models to become sophisticated enough for us to map, in such unprecedented detail, a system as complicated as MCS J0416.1–2403," says team member Jean-Paul Kneib.

By studying 57 of the most reliably and clearly lensed galaxies, the astronomers modelled the mass of both normal and dark matter within MCS J0416.1-2403. "Our map is twice as good as any previous models of this cluster!" adds Jauzac.

The total mass within MCS J0416.1-2403 — modelled to be over 650 000 light-years across — was found to be 160 trillion times the mass of the Sun. This measurement is several times more precise than any other cluster map, and is the most precise ever produced [4]. By precisely pinpointing where the mass resides within clusters like this one, the astronomers are also measuring the warping of space-time with high precision.

"Frontier Fields' observations and gravitational lensing techniques have opened up a way to very precisely characterise distant objects — in this case a cluster so far away that its light has taken four and a half billion years to reach us," adds Jean-Paul Kneib. "But, we will not stop here. To get a full picture of the mass we need to include weak lensing measurements too. Whilst it can only give a rough estimate of the inner core mass of a cluster, weak lensing provides valuable information about the mass surrounding the cluster core."

The team will continue to study the cluster using ultra-deep Hubble imaging and detailed strong and weak lensing information to map the outer regions of the cluster as well as its inner core, and will thus be able to detect substructures in the cluster's surroundings. They will also take advantage of X-ray measurements of hot gas and spectroscopic redshifts to map the contents of the cluster, evaluating the respective contribution of dark matter, gas and stars [5].

Combining these sources of data will further enhance the detail of this mass distribution map, showing it in 3D and including the relative velocities of the galaxies within it. This paves the way to understanding the history and evolution of this galaxy cluster.

The results of the study will be published online in Monthly Notices of the Royal Astronomical Society on 24 July 2014.

Notes

[1] The cluster is also known as MACS J0416.1–2403.

[2] The warping of space-time by large objects in the Universe was one of the predictions of Albert Einstein’s theory of general relativity.

[3] Gravitational lensing is one of the few methods astronomers have to find out about dark matter. Dark matter, which makes up around three quarters of all matter in the Universe, cannot be seen directly as it does not emit or reflect any light, and can pass through other matter without friction (it is collisionless). It interacts only by gravity, and its presence must be deduced from its gravitational effects.

[4] The uncertainty on the measurement is only around 0.5%, or 1 trillion times the mass of the sun. This may not seem precise but it is for a measurement such as this.

[5] NASA's Chandra X-ray Observatory was used to obtain X-ray measurements of hot gas in the cluster and ground based observatories provide the data needed to measure spectroscopic redshifts.

Notes for editors

The Hubble Space Telescope is a project of international cooperation between ESA and NASA.

The international team of astronomers in this study consists of M. Jauzac (Durham University, UK and Astrophysics & Cosmology Research Unit, South Africa); B. Clement (University of Arizona, USA); M. Limousin (Laboratoire d’Astrophysique de Marseille, France and University of Copenhagen, Denmark); J. Richard (Université Lyon, France); E. Jullo (Laboratoire d’Astrophysique de Marseille, France); H. Ebeling (University of Hawaii, USA); H. Atek (Ecole Polytechnique Fédérale de Lausanne, Switzerland); J.-P. Kneib (Ecole Polytechnique Fédérale de Lausanne, Switzerland and Laboratoire d’Astrophysique de Marseille, France); K. Knowles (University of KwaZulu-Natal, South Africa); P. Natarajan (Yale University, USA); D. Eckert (University of Geneva, Switzerland); E. Egami (University of Arizona, USA); R. Massey (Durham University, UK); and M. Rexroth (Ecole Polytechnique Fédérale de Lausanne, Switzerland).

More information

Image credit: ESA/Hubble, NASA, HST Frontier Fields

Acknowledgement: Mathilde Jauzac (Durham University, UK and Astrophysics & Cosmology Research Unit, South Africa) and Jean-Paul Kneib (École Polytechnique Fédérale de Lausanne, Switzerland)

Links

• Images of Hubble
• Paper in Monthly Notices of the Royal Astronomical Society
• Science paper
• University of Hawaii Institute for Astronomy press release

Contacts

Mathilde Jauzac
Durham University, Institute for Computational Cosmology
Durham, United Kingdom
Tel: +33 6 52 67 15 39 (France)
Cell: +44 7445 218614 (UK)
Email: mathilde.jauzac@dur.ac.uk

Jean-Paul Kneib
École Polytechnique Fédérale de Lausanne, Observatoire de Sauverny
Versoix, Switzerland
Tel: +41 22 3792473
Cell: +33 695 795 392
Email: jean-paul.kneib@epfl.ch

Eric Jullo
Laboratoire d'Astrophysique de Marseille
Marseille, France
Tel: +33 4 91 05 5951
Email: eric.jullo@lam.fr

Johan Richard
Centre de Recherche Astronomique de Lyon, Observatoire de Lyon
Lyon, France
Tel: +33 478 868 378
Email: johan.richard@univ-lyon1.fr

Georgia Bladon
ESA/Hubble, Public Information Officer
Garching bei München, Germany
Tel: +44 7816291261
Email: gbladon@partner.eso.org

Source: ESA/Hubble - Space Telescope