Wednesday, October 08, 2025

Starbursting centre

A spiral galaxy with large, open arms. A bar of yellow light, where old stars are gathered, crosses the middle of the disk. The very centre is a white point surrounded by a small, shining ring of star clusters. Thin lanes of dust swirl around this ring, reaching out to follow the spiral arms; also visible across the arms are red, glowing spots where stars are forming. To the right a star shines large and bright. Credit: ESA/Hubble & NASA, L. C. Ho, G. Brammer, A. Filippenko, C. Kilpatrick

The glittering galaxy in this NASA/ESA Hubble Space Telescope Picture of the Week is NGC 6951, which resides about 70 million light-years away in the constellation Cepheus.

As this Hubble image shows, NGC 6951 is a spiral galaxy with plenty of intriguing structures. Most eye-catching are its spiral arms, which are dotted with brilliant red nebulae, bright blue stars and filamentary dust clouds. The spiral arms loop around the galactic centre, which has a golden glow that comes from a population of older stars. The centre of the galaxy is also distinctly elongated, revealing the presence of a slowly rotating bar of stars.

NGC 6951’s bar may be responsible for another remarkable feature: a white-blue ring that encloses the very heart of the galaxy. This is called a circumnuclear starburst ring — essentially, a circle of enhanced star formation around the nucleus of a galaxy. The bar funnels gas toward the centre of the galaxy, where it collects in a ring about 3800 light-years across. Two dark dust lanes that run parallel to the bar mark the points where gas from the bar enters the ring.

The dense gas of a circumnuclear starburst ring is the perfect environment to churn out an impressive number of stars. Using data from Hubble, astronomers have identified more than 80 potential star clusters within NGC 6951’s ring. Many of the stars formed less than 100 million years ago, but the ring itself is longer-lived, potentially having existed for 1–1.5 billion years.

Astronomers have imaged NGC 6951 with Hubble for a wide variety of reasons, including mapping the dust in nearby galaxies, studying the centres of disc galaxies and keeping tabs on recent supernovae (of which NGC 6951 has hosted five or six).




Tuesday, October 07, 2025

Most powerful 'odd radio circle' to date is discovered

A still image from the animation of RAD J131346.9+500320
Credit: RAD@home Astronomy Collaboratory (India)
Licence type:Attribution (CC BY 4.0)

The most distant and most powerful 'odd radio circle' (ORC) known so far has been discovered by astronomers.

These curious rings are a relatively new astronomical phenomenon, having been detected for the first time just six years ago. Only a handful of confirmed examples are known – most of which are 10-20 times the size of our Milky Way galaxy.

ORCs are enormous, faint, ring-shaped structures of radio emission surrounding galaxies which are visible only in the radio band of the electromagnetic spectrum and consist of relativistic, magnetised plasma. Previous research has suggested they might be caused by shockwaves from merging supermassive black holes or galaxies.

Now, a new study published today in Monthly Notices of the Royal Astronomical Society proposes that the rings of light may actually be linked to superwind outflows from spiral host radio galaxies.

Researchers led by the University of Mumbai made their discovery with the help of the RAD@home Astronomy Collaboratory citizen science platform and the Low-Frequency Array (LOFAR), the world's largest and most sensitive radio telescope operating at low frequencies (10 to 240 megahertz).

The source, designated RAD J131346.9+500320, lies nearly at redshift ~0.94 (when the universe was half its current age), making it both the most distant and the most powerful ORC known to date.

It also has not one but two intersecting rings – only the second such example with this feature – sparking more questions than answers.

RGB image from the Legacy Surveys, overlaid with radio emission in red from the LOFAR Two-Metre Sky Survey (LoTSS), showing the 'odd radio circle' (ORC) RAD J131346.9+500320.
RAD@home Astronomy Collaboratory (India)
Licence type:Attribution (CC BY 4.0)

Dr Ananda Hota, founder of the RAD@home Astronomy Collaboratory for citizen science research, said: "This work shows how professional astronomers and citizen scientists together can push the boundaries of scientific discovery.

"ORCs are among the most bizarre and beautiful cosmic structures we've ever seen – and they may hold vital clues about how galaxies and black holes co-evolve, hand-in-hand."

RAD J131346.9+500320 is the first ORC discovered through citizen science and the first identified with the help of LOFAR.

LOFAR is a cutting-edge pan-European radio telescope, with hundreds of thousands of simple antennas spread across the Netherlands and partner stations in many European countries. Working together as one giant interferometer, it provides an exceptionally sharp and sensitive view of the sky at low radio frequencies.

It enables astronomers to look back billions of years to a time before the first stars and galaxies formed by surveying vast areas of the low-frequency radio sky.

Alongside the new ORC discovery, the RAD@home Astronomy Collaboratory also found two other unusual cosmic giants.

The first, RAD J122622.6+640622, is a galaxy nearly three million light-years across – more than 25 times the size of our Milky Way. One of its powerful jets suddenly bends sideways, as if forced off course, and then blows a spectacular radio ring about 100,000 light-years wide.
Animation of ORC
An artistic visualisation of the rare twin-ring ORC (RAD J131346.9+500320), expanding outward after an explosive event in the central galaxy. Credit: RAD@home Astronomy Collaboratory (India).ORC animation still.. Caption: A still image from the animation of RAD J131346.9+500320. Credit: RAD@home Astronomy Collaboratory (India)

The second, RAD J142004.0+621715, stretches across 1.4 million light-years and shows a similar ring of radio emission at the end of one of its jets, with another narrow radio jet on the other side of the host galaxy.

Both galaxies sit in crowded regions of space called galaxy clusters, where their jets likely interact with surrounding matter, million degree hot thermal plasma, which shapes these striking cosmic structures.

All three objects are found in galaxy clusters weighing about 100 trillion Suns, suggesting that interactions of relativistic magnetised plasma jets with the surrounding hot thermal plasma may help shape these rare rings.

Co-author Dr Pratik Dabhade, of the National Centre for Nuclear Research in Warsaw, Poland, said: "These discoveries show that ORCs and radio rings are not isolated curiosities – they are part of a broader family of exotic plasma structures shaped by black hole jets, winds, and their environments.

"The fact that citizen scientists uncovered them highlights the continued importance of human pattern recognition, even in the age of machine learning."

With upcoming facilities such as the Square Kilometre Array (SKA), astronomers expect many more ORCs to be uncovered.

At the same time, new optical surveys such as the Dark Energy Spectroscopic Instrument (DESI) and the Vera C. Rubin Observatory's Large Synoptic Survey Telescope (LSST) will provide the redshifts and environments of their host galaxies, helping to piece together how these mysterious rings form and evolve.

For now, the three new cosmic rings – discovered not by automated software but by sharp-eyed citizen scientists – represent an important step toward un,brlocking the secrets of these vast, puzzling structures.

Submitted by Sam Tonkin 
 


Media contacts

Sam Tonkin
Royal Astronomical Society
Mob: +44 (0)7802 877 700

press@ras.ac.uk



Science contacts:

Dr Ananda Hota
UM-DAE CEBS & CETACS, University of Mumbai, India
RAD@home Astronomy Collaboratory

hotaananda@gmail.com

Dr Pratik Dabhade
Astrophysics Division, National Centre for Nuclear Research, Warsaw, Poland

pratik.dabhade@ncbj.gov.pl



Images & captions

Odd Radio Circle

Caption: Optical RGB image from the Legacy Surveys, overlaid with radio emission in red from the LOFAR Two-Metre Sky Survey (LoTSS), showing the 'odd radio circle' (ORC) RAD J31346.9+500320. Credit: RAD@home Astronomy Collaboratory (India) 




Further information

The paper‘RAD@home discovery of extragalactic radio rings and odd radio circles: clues to their origins’ by Ananda Hota and Pratik Dabhade et all. has been published in Monthly Notices of the Royal Astronomical Society. DOI: 10.1093/mnras/staf1531.



Notes for editors

About the Royal Astronomical Society

The Royal Astronomical Society (RAS), founded in 1820, encourages and promotes the study of astronomy, solar-system science, geophysics and closely related branches of science.

The RAS organises scientific meetings, publishes international research and review journals, recognises outstanding achievements by the award of medals and prizes, maintains an extensive library, supports education through grants and outreach activities and represents UK astronomy nationally and internationally. Its more than 4,000 members (Fellows), a third based overseas, include scientific researchers in universities, observatories and laboratories as well as historians of astronomy and others.

The RAS accepts papers for its journals based on the principle of peer review, in which fellow experts on the editorial boards accept the paper as worth considering. The Society issues press releases based on a similar principle, but the organisations and scientists concerned have overall responsibility for their content.


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Monday, October 06, 2025

Six billion tonnes a second: Rogue planet found growing at record rate

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Illustration of the rogue planet Cha 1107-7626

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Location in the sky of the rogue planet Cha 1107-7626 (infrared)

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Location in the sky of the rogue planet Cha 1107-7626 (visible light)



Videos

Rogue planet found growing at record rate | ESO News
PR Video eso2516a
Rogue planet found growing at record rate | ESO News

Zooming in on the rogue planet Cha 1107-7626
PR Video eso2516b
Zooming in on the rogue planet Cha 1107-7626

Animation of the growth spurt in the rogue planet Cha 1107-7626
PR Video eso2516c
Animation of the growth spurt in the rogue planet Cha 1107-7626

Animation of the growth spurt in the rogue planet Cha 1107-7626
PR Video eso2516d
Animation of the growth spurt in the rogue planet Cha 1107-7626



Astronomers have identified an enormous ‘growth spurt’ in a so-called rogue planet. Unlike the planets in our Solar System, these objects do not orbit stars, free-floating on their own instead. The new observations, made with the European Southern Observatory’s Very Large Telescope (ESO’s VLT), reveal that this free-floating planet is eating up gas and dust from its surroundings at a rate of six billion tonnes a second. This is the strongest growth rate ever recorded for a rogue planet, or a planet of any kind, providing valuable insights into how they form and grow.

People may think of planets as quiet and stable worlds, but with this discovery we see that planetary-mass objects freely floating in space can be exciting places,” says Víctor Almendros-Abad, an astronomer at the Astronomical Observatory of Palermo, National Institute for Astrophysics (INAF), Italy and lead author of the new study.

The newly studied object, which has a mass five to 10 times the mass of Jupiter, is located about 620 light-years away in the constellation Chamaeleon. Officially named Cha 1107-7626, this rogue planet is still forming and is fed by a surrounding disc of gas and dust. This material constantly falls onto the free-floating planet, a process known as accretion. However, the team led by Almendros-Abad has now found that the rate at which the young planet is accreting is not steady.

By August 2025, the planet was accreting about eight times faster than just a few months before, at a rate of six billion tonnes per second! “This is the strongest accretion episode ever recorded for a planetary-mass object,” says Almendros-Abad. The discovery, published today in The Astrophysical Journal Letters, was made with the X-shooter spectrograph on ESO’s VLT, located in Chile’s Atacama Desert. The team also used data from the James Webb Space Telescope, operated by the US, European and Canadian space agencies, and archival data from the SINFONI spectrograph on ESO's VLT.

"The origin of rogue planets remains an open question: are they the lowest-mass objects formed like stars, or giant planets ejected from their birth systems?” asks co-author Aleks Scholz, an astronomer at the University of St Andrews, United Kingdom. The findings indicate that at least some rogue planets may share a similar formation path to stars since similar bursts of accretion have been spotted in young stars before. As co-author Belinda Damian, also an astronomer at the University of St Andrews, explains: “This discovery blurs the line between stars and planets and gives us a sneak peek into the earliest formation periods of rogue planets.”

By comparing the light emitted before and during the burst, astronomers gathered clues about the nature of the accretion process. Remarkably, magnetic activity appears to have played a role in driving the dramatic infall of mass, something that has only been observed in stars before. This suggests that even low-mass objects can possess strong magnetic fields capable of powering such accretion events. The team also found that the chemistry of the disc around the planet changed during the accretion episode, with water vapour being detected during it but not before. This phenomenon had been spotted in stars but never in a planet of any kind.

Free-floating planets are difficult to detect, as they are very faint, but ESO’s upcoming Extremely Large Telescope (ELT), operating under the world's darkest skies for astronomy, could change that. Its powerful instruments and giant main mirror will enable astronomers to uncover and study more of these lonely planets, helping them to better understand how star-like they are. As co-author and ESO astronomer Amelia Bayo puts it: “The idea that a planetary object can behave like a star is awe-inspiring and invites us to wonder what worlds beyond our own could be like during their nascent stages.”

Source: ESO/News



More information

This research was presented in a paper titled “Discovery of an Accretion Burst in a Free-Floating Planetary-Mass Object” to appear in The Astrophysical Journal Letters (doi:10.3847/2041-8213/ae09a8).

The team is composed of  V. Almendros-Abad (Istituto Nazionale di Astrofisica - Osservatorio Astronomico di Palermo, Italy), Aleks Scholz (School of Physics & Astronomy, University of St Andrews, United Kingdom [St Andrews]), Belinda Damian (St Andrews), Ray Jayawardhana (Department of Physics & Astronomy, Johns Hopkins University, USA [JHU]), Amelia Bayo (European Southern Observatory, Germany), Laura Flagg (JHU), Koraljka Mužić (Instituto de Astrofísica e Ciências do Espaço, Faculdade de Ciências, Universidade de Lisboa, Portugal), Antonella Natta (School of Cosmic Physics, Dublin Institute for Advanced Studies and University College Dublin, Ireland) Paola Pinilla (Mullard Space Science Laboratory, University College London, UK) and Leonardo Testi (Dipartimento di Fisica e Astronomia, Università di Bologna, Italy).

The European Southern Observatory (ESO) enables scientists worldwide to discover the secrets of the Universe for the benefit of all. We design, build and operate world-class observatories on the ground — which astronomers use to tackle exciting questions and spread the fascination of astronomy — and promote international collaboration for astronomy. Established as an intergovernmental organisation in 1962, today ESO is supported by 16 Member States (Austria, Belgium, Czechia, Denmark, France, Finland, Germany, Ireland, Italy, the Netherlands, Poland, Portugal, Spain, Sweden, Switzerland and the United Kingdom), along with the host state of Chile and with Australia as a Strategic Partner. ESO’s headquarters and its visitor centre and planetarium, the ESO Supernova, are located close to Munich in Germany, while the Chilean Atacama Desert, a marvellous place with unique conditions to observe the sky, hosts our telescopes. ESO operates three observing sites: La Silla, Paranal and Chajnantor. At Paranal, ESO operates the Very Large Telescope and its Very Large Telescope Interferometer, as well as survey telescopes such as VISTA. Also at Paranal, ESO will host and operate the south array of the Cherenkov Telescope Array Observatory, the world’s largest and most sensitive gamma-ray observatory. Together with international partners, ESO operates ALMA on Chajnantor, a facility that observes the skies in the millimetre and submillimetre range. At Cerro Armazones, near Paranal, we are building “the world’s biggest eye on the sky” — ESO’s Extremely Large Telescope. From our offices in Santiago, Chile we support our operations in the country and engage with Chilean partners and society.




Links



Contacts

Víctor Almendros-Abad
INAF Astronomical Observatory of Palermo
Palermo, Italy
Tel: +39 3762144093
Email:
victor.almendrosabad@inaf.it

Aleks Scholz
University of St. Andrews
St. Andrews, United Kingdom
Tel: +44 (0)1334 46 1668
Email:
as110@st-andrews.ac.uk

Belinda Damian
University of St. Andrews
St. Andrews, United Kingdom
Tel: +44 (0)1334 46 3098
Email:
bd64@st-andrews.ac.uk

Amelia Bayo
European Southern Observatory
Garching, Germany
Tel: +49 89 3200 6499
Email:
AmeliaMaria.BayoAran@eso.org

Bárbara Ferreira
ESO Media Manager
Garching, Germany
Tel: +49 89 3200 6670
Cell: +49 151 241 664 00
Email:
press@eso.org


Sunday, October 05, 2025

ALMA Sees Super Stellar Nurseries at Heart of Sculptor Galaxy

What is the recipe for starburst? Astronomers studied NGC 253 with ALMA to find out. These new ALMA data reveal a diffuse envelope of carbon monoxide gas (shown in red), which surrounds stellar nurseries — regions of active star formation (in yellow). By dissecting these regions with ALMA, astronomers are uncovering clues to the processes and conditions that drive furious star formation. The ALMA data are superimposed on a Hubble image that covers part of the same region. Credit: B. Saxton (NRAO/AUI/NSF); ALMA (NRAO/ESO/NAOJ); A. Leroy; STScI/NASA, ST-ECF/ESA, CADC/NRC/CSA

.

Technical Details


Telescope: ALMA; ALMA; HST; HST; HST
Band: ALMA Band 3 CO; ALMA Band 3 CO; R; G; B
Date: 2012-01-09T21:28:03.216000; 2012-07-02T09:15:31.488000; 2008-01-16T08:40:57; 2008-01-16T08:40:01; 2008-01-16T08:40:57
Center: RA 0:47:36.42, Dec: -25:16:47.04
Field of View: 1.7 x 1.7 arcminutes



NuSTAR Observes the Rosetta Stone of Accreting Millisecond Pulsars

Artist's impression of the extreme environment around an accreting millisecond pulsar.
Image credit: NASA/GSFC -
Download Image

During the past week NuSTAR observed the "Rosetta Stone" of accreting millisecond X-ray pulsars (AMXP)—SAX J1808.4-3658. This observation was crucial in understanding the spectral timing properties during the decay phase of its 2025 outburst, one of the longest, if not the longest ever observed. SAX J1808 is also the only known AMXP to show coherent optical and X-ray pulsations and so the NuSTAR observation was coordinated with optical fast photometry using the LightSpeed instrument on the Magellan telescope. Analysis of these coordinated observations will be very important to understand the physics behind these coherent optical pulsations. NuSTAR will aid in comparing the X-ray pulse period, pulse shape, and any phase lag with the same in the optical domain. Moreover, this observation, together with a previous NuSTAR Director's Discretionary Time observation, has provided high-energy X-ray coverage to an ongoing multiwavelength campaign on SAX J1808 including lower energy X-ray observations by NASA’s Gehrels-Swift and ESA’s XMM-Newton telescopes, optical observations using the 6.5 meter Megellan telescopes at the Las Campanas Observatory in Chile, and the Giant Metrewave Radio Telescope (GMRT) near Pune, India.

Authors: Sayantan Bhattacharya (Research Associate, Tata Institute of Fundamental Research, Mumbai)



Saturday, October 04, 2025

New Instrument at SOAR Achieves First Light with Observations of Remarkable Binary Star System

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STELES Spectrum of Eta Carinae

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STELES Spectrum of Eta Carinae

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Blue Spectrum of Eta Carinae

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Red Spectrum of Eta Carinae

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STELES on SOAR

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The SOAR Telescope



The high-resolution SOAR Telescope Echelle Spectrograph brings a powerful new tool to explore the Southern Hemisphere sky

The SOAR Telescope, located on Cerro Pachón in Chile, has received a major upgrade with the installation of the SOAR Telescope Echelle Spectrograph (STELES). The long-awaited instrument achieved first light in August with observations of the binary star system Eta Carinae, along with 13 other targets. SOAR is part of U.S. National Science Foundation Cerro Tololo Inter-American Observatory (CTIO), a Program of NSF NOIRLab.

The SOAR Telescope Echelle Spectrograph (STELES), a new instrument on the 4.1-meter Southern Astrophysical Research (SOAR) Telescope, has achieved first light. STELES was installed on the SOAR Telescope on 30 July 2025 and on 6 August, from its perch on Cerro Pachón in Chile, it pointed toward the constellation Carina to observe one of the most fascinating pairs of stars in our Milky Way — Eta Carinae.

Eta Carinae is a binary star system — two stars orbiting each other — with a long and curious history of brightening and dimming. The system is best known for its ‘Great Eruption’ in 1837, during which it underwent a tremendous explosion and became one of the brightest objects in the night sky, before dimming again. In the centuries since, astronomers have watched Eta Carinae as it mysteriously fluctuates in brightness

Current estimates hold that Eta Carinae’s larger star is about 90 times the mass of the Sun, whereas the smaller star is around 30 times the mass of the Sun. And while the system is greater than five million times more luminous than the Sun, it appears faint in our sky due to being heavily obscured by the Homunculus Nebula — a cloud of material ejected from the larger star during the Great Eruption.

This fascinating object was chosen as a first light target for STELES in recognition of Brazilian astronomer Augusto Damineli, who was the first to propose that Eta Carinae was a binary system and who led the acquisition of most of the funding necessary for the construction and installation of STELES at SOAR.

STELES was designed in Brazil by the Laboratório Nacional de Astrofísica (LNA), part of the Ministério da Ciência, Tecnologia e Inovação (MCTI), and the Instituto de Astronomia, Geofísica e Ciências Atmosféricas from Universidade de São Paulo (IAG/USP). The optical design was done by Bernard Delabre from ESO. Components for the instrument’s CCD detectors were designed, fabricated, and tested at CTIO.

The instrument arrived at CTIO in May 2016 with a substantial amount of assembly and testing still needed. For the next nine years the teams worked diligently, overcoming logistical and technical challenges, delays due to the COVID-19 pandemic, and the need for multiple excursions from Brazil to Chile. On the night of first light, the teams felt a true sense of accomplishment as STELES successfully acquired the spectra of 14 stars, galaxies, and planetary nebulae.

“First light marks the achievement of a major milestone, and we celebrate it as a joint achievement of the LNA and the CTIO/SOAR teams,” says Felipe Navarete, researcher at LNA and STELES instrument scientist.

STELES works by dividing a beam of incoming light into two arms, one for the short wavelengths of blue light (300–550 nanometers) and one for longer wavelengths of red light (530–890 nanometers). Echelle gratings in each arm act similarly to a prism, further separating each section of light into its spectrum of constituent colors. The spectrum can tell scientists detailed information about an object’s chemical composition, motion, rotation, and distance.

STELES can see a wide range of visible light in a single shot, meaning it can capture most of the photons that reach it. This large light-collecting capability, combined with a sophisticated detector system and the excellent image quality of the SOAR Telescope, allows STELES to quickly take precise measurements of faint distant stars.

With the high-quality data provided by STELES, scientists will be able to study large numbers of metal-poor stars in and outside of our galaxy. Specifically, STELES will search for the theorized first generation of stars, known as Population III, which are the earliest born stars in the Universe’s history and contain virtually no metals — elements heavier than helium. These oldest stars have never been directly observed.

“STELES will undoubtedly enhance SOAR’s spectroscopic capabilities and will be a boon for researchers in the U.S. and Brazil,” says NSF Program Director Chris Davis. “STELES offers a unique combination of high spectral resolution and ultraviolet capability, making it a powerful tool for advancing our understanding of star and planet formation, the interstellar medium, and hot stars.”

Scientists anticipate that STELES data will provide insight into the chemical evolution of the Milky Way and unveil secrets of the early Universe. Following some additional on-sky engineering tests, STELES will begin its pioneering search for the Universe’s oldest stars in early 2026.




More information

The Southern Astrophysical Research (SOAR) Telescope is a joint project of the Ministério da Ciência, Tecnologia e Inovações do Brasil (MCTIC/LNA), NSF NOIRLab, the University of North Carolina at Chapel Hill (UNC), and Michigan State University (MSU).

NSF NOIRLab, the U.S. National Science Foundation center for ground-based optical-infrared astronomy, operates the International Gemini Observatory (a facility of NSF, NRC–Canada, ANID–Chile, MCTIC–Brazil, MINCyT–Argentina, and KASI–Republic of Korea), NSF Kitt Peak National Observatory (KPNO), NSF Cerro Tololo Inter-American Observatory (CTIO), the Community Science and Data Center (CSDC), and NSF–DOE Vera C. Rubin Observatory (in cooperation with DOE’s SLAC National Accelerator Laboratory). It is managed by the Association of Universities for Research in Astronomy (AURA) under a cooperative agreement with NSF and is headquartered in Tucson, Arizona.

The scientific community is honored to have the opportunity to conduct astronomical research on I’oligam Du’ag (Kitt Peak) in Arizona, on Maunakea in Hawai‘i, and on Cerro Tololo and Cerro Pachón in Chile. We recognize and acknowledge the very significant cultural role and reverence of I’oligam Du’ag to the Tohono O’odham Nation, and Maunakea to the Kanaka Maoli (Native Hawaiians) community.



Links



Contacts:

Josie Fenske
Public Information Officer
NSF NOIRLab
Email:
josie.fenske@noirlab.edu


A New Model of Water in Jupiter's Atmosphere

An illustration of Jupiter's atmosphere at varying depths. Deeper below the cloud layer, water concentrations increase.
Credit: H. Ge

Caltech researchers have developed a new simulation of the hydrological cycle on Jupiter, modeling how water vapor condenses into clouds and falls as rain throughout the giant planet's swirled, turbulent atmosphere. The research shows that Jupiter's water is not uniformly distributed, giving missions like NASA's Juno orbiter important guidance about where to look for water on the planet.

An illustration of Jupiter's atmosphere at varying depths. Deeper below the cloud layer, water concentrations increase. Credit: H. Ge
Jupiter was considered the first planet in our solar system to form, and its massive gravitational influence shaped the orbital architecture of Earth and the other planets in the solar system. Understanding how much water Jupiter has, and where to look for it, gives clues to how water arrived on Earth, which is still an open question in planetary science.

The research is described in a paper appearing in the journal Proceedings of the National Academy of Sciences on September 29. The study's first author is Huazhi Ge, a postdoctoral scholar in the group of Andrew P. Ingersoll, professor of planetary science, emeritus.

"While we are focusing on Jupiter, ultimately we are trying to create a theory about water and atmospheric dynamics that can broadly be applied to other planets, including exoplanets," Ge says.

Jupiter's swirled appearance results from its atmospheric dynamics, which, while visually striking, make it difficult to determine the abundances of chemical species such as water and metals. The Galileo mission first detected water on Jupiter near its equator in the 1990s, but it remained uncertain if that water was distributed evenly across the giant planet. The new model accounts for Jupiter's rapid rotation—one full rotation, or one day, on Jupiter takes only about 10 Earth hours. This fast rotation causes the turbulent stripes visible on Jupiter's atmosphere. The new model suggests that this turbulence in the subtropic and mid-latitudes leads to rain that draws water deeper beneath the cloud layer, making the planet's lower atmosphere more humid tens of kilometers beneath the clouds.

Jupiter is different from Earth in many ways, so modeling its atmospheric dynamics—and then comparing those models with observations—leads to a better understanding of a diverse range of planets more broadly. Next, the team plans to create a more global model, expanding past the mid-latitudes. Ideally, the theory can be applied to other gas giants like Uranus and Neptune that also have nonuniform distributions of chemical species like methane rather than water.

The paper is titled "Non-Uniform Water Distribution in Jupiter's Mid-Latitudes: Influence of Precipitation and Planetary Rotation." In addition to Ge and Ingersoll, coauthors are Cheng Li of the University of Michigan, Xi Zhang of UC Santa Cruz, and Caltech graduate student Sihe Chen. Funding was provided by NASA, UC Santa Cruz, the Heising-Simons Foundation, and the National Science Foundation.

Written by Lori Dajose

Source: Caltech/News



Contact:

Lori Dajose
(626) 395‑1217

ldajose@caltech.edu


Friday, October 03, 2025

Nuclear star clusters boost the growth of intermediate mass black holes

The low-mass galaxy NGC 300 (left) hosts a compact nuclear star cluster at its centre that can be resolved using an image from the Hubble Space Telescope (middle). A similar nuclear star cluster is included in the simulations (right). Credit: left: Adam Block/Mount Lemmon SkyCenter/University of Arizona; middle: Carson et al. (2015); right: MPA/Partmann et al. (2025).

Growth of IMBHs of different initial mass in the center of a simulated galaxy. Solid lines show growth without a nuclear star cluster, while dashed lines show growth with one. Low-mass black holes (red, blue and orange lines) only grow when embedded in a nuclear star cluster, whereas more massive black holes, which are comparable in mass to the nuclear star cluster itself, show little additional growth (green line). The nuclear star cluster contains 500,000 solar masses of stars, representing a few percent of the galaxy’s total stellar mass. Credit: MPA/Partmann



Black holes with masses between the stellar and supermassive regime are among the most elusive objects in the Universe. These intermediate-mass black holes are believed to reside in many dwarf galaxies. Using new, high-resolution supercomputer simulations, MPA scientists discovered that nuclear star clusters — compact, massive clusters of stars at the centres of galaxies — may be key to enabling these black holes to grow, thus shedding light on the origins of supermassive black holes.

All massive galaxies, including our own Milky Way, contain supermassive black holes at their centres, with masses ranging from millions to billions of solar masses. However, the formation and growth of these giants remains a mystery. Low-mass galaxies may hold the answer: some of them contain these elusive intermediate-mass black holes (IMBHs), which have masses ranging from hundreds to hundreds of thousands of times that of the Sun. These are more massive than stellar black holes, but have never reached the supermassive stage. IMBHs exert influence only in a tiny region around them. This makes it difficult for them to capture gas and stars, affect their host galaxies, or even be detected in the first place.

Many low-mass galaxies host nuclear star clusters: extremely dense systems of stars spanning only a few light years, yet containing a few percent of the entire galaxy’s stellar mass. Nuclear star clusters form an extremely compact and deep potential well at the centre of the galaxy. Recent observations suggest a strong correlation between nuclear star clusters and the existence of IMBHs at their centres. The nuclear star clusters in low-mass galaxies tend to be more massive than their IMBHs, and may play a crucial role in the evolution of galactic centres. The MPA team set out to study how such an environment affects IMBH growth.

Simulating black hole growth is complex as it requires tracking how interstellar gas flows from galactic scales down to the tiny sphere of influence of the black hole. The team of researchers used high-resolution simulations that resolve the black hole's sphere of influence and capture many relevant physical processes in the interstellar gas. The simulations also follow millions of individual stars, including the radiation they emit and the supernovae of the most massive ones. By heating and stirring the gas, these processes strongly influence whether black holes can feed and grow.

The team tested low-mass galaxies with IMBHs of different initial masses. They found that light IMBHs (those below 10,000 solar masses) are barely able to capture gas and grow unless a nuclear star cluster is present. If the IMBH is embedded in a cluster, its additional gravitational potential enables rapid gas accretion and swift black hole growth. More massive IMBHs accrete efficiently even without a nuclear star cluster, but the additional growth is small compared to their initial mass. This demonstrates that nuclear star clusters are particularly significant for the smallest black holes, where the cluster's mass far exceeds that of the black hole itselfas is typical in low-mass galaxies.

Even with a nuclear star cluster, growth can be easily disrupted by stellar feedback. Some of the gas captured by the nuclear star cluster forms stars, including massive stars. When these massive stars end their lives as supernovae, they can expel gas from the galaxy’s centre, temporarily starving the black hole. Consequently, IMBHs undergo cycles of activity and quiet phases. This means that many are likely to be missed in current surveys, which typically detect only actively feeding black holes through the radiation produced by the accretion process.

The study shows that nuclear star clusters are essential for the growth of intermediate-mass black holes in low-mass galaxies, which would otherwise remain stagnant. This is particularly exciting because many theories suggest that the first black hole seeds in the early Universe formed through stellar collisions inside such clusters. Therefore, the new results point not only to nuclear star clusters as the birthplace of intermediate-mass black holes, but also as the sites where they grow most efficiently.

Interstellar gas (top left) is stirred by radiation and supernova explosions from massive stars, creating hot, low-density regions (top middle). Occasionally, the IMBH captures gas (bottom left), fuelling growth and star formation in the galactic centre. In the IMBH’s immediate surroundings (bottom middle and right), supernovae clear gas from the galaxy’s core, temporarily stopping black hole feeding. Once most massive stars have exploded, new gas can be captured by the black hole. Stars with masses greater than 8 solar masses (and their potential massive remnants) are depicted as red, orange, and yellow star symbols, with colour indicating increasing mass.




Author:

Christian Partmann

partmann@mpa-Garching.mgp.de

Thorsten Naab
Scientific Staff
tnaab@mpa-garching.mpg.de

Original publication

Christian Partmann, Thorsten Naab, Natalia Lahén, Antti Rantala, Michaela Hirschmann, Jessica M Hislop, Jonathan Petersson, Peter H Johansson
The importance of nuclear star clusters for massive black hole growth and nuclear star formation in simulated low-mass galaxies
Monthly Notices of the Royal Astronomical Society, Volume 537, Issue 2, February 2025, Pages 956–977

Source


Clouds in the Wind: Why Cold Gas Fades in Galactic Outflows


The observation (top) of the M82 galaxy shows the emission of a particular molecule (PAH = molecules of poly-aromatic hydrocarbon) in the infrared band of JWST's NIRCam. The leftmost plume is enlarged in the left image. The simulation (bottom) also shows the emission map. The inset shows one projection of the emission field, the larger image shows the total emission (the projection of many such slices along the z-axis). The blue arrows indicate the direction of the head-tail gradient in emission from cold gas along the direction of the wind in both simulations and observations. Credit: Observation: Fisher et al 2025; simulation: MPA, A. Dutta



A new study led by Dr. Alankar Dutta at the Max Planck Institute for Astrophysics uncovers why cold gas clouds fail to thrive in powerful winds flowing out of galaxies driven by supernovae. These findings, soon to be published in the Monthly Notices of the Royal Astronomical Society, challenge long standing assumptions about how galaxies exchange matter with their surroundings.

Galactic outflows — giant winds driven by intense star formation — play a key role in shaping the evolution of galaxies. These outflows carry gas, dust, and heavy elements out of the galactic disks and into the surrounding gaseous environment, the circumgalactic medium (CGM). While we know that these winds are multiphase, i.e. containing both hot, ionized plasma and much colder, denser neutral gas, as well as molecular gas. The origin of the hot gas in outflows can be attributed to the highly energetic supernovae explosions that drive them. However, the fate of the cold gas in these outflows and how this survives such a hot and hostile environment has long puzzled astronomers.

In simulations, it has been particularly challenging to resolve and infer the dynamics of the cold component which occur as clumpy parsec/sub-parsec sized clouds in large kilo-parsec scale outflows. This has caused astronomers to turn to idealized wind tunnel simulations to study cloud-wind interactions. Many previous studies used idealized setups where cold clouds face a uniform hot wind from the inner regions of galaxies, but real galactic outflows are not uniform. They expand, and that expansion fundamentally alters the game. To capture this realistic behavior, the group ran high-resolution hydrodynamic simulations of cold gas clouds embedded in expanding galactic winds. A well-known model of starburst-driven outflows formed the basis for the wind’s structure.

The new simulations reveal that as the clouds move outward, they remain in local pressure balance with the background wind. This leads to a steep decline in their density contrast, which means that over time, these clouds become increasingly diffuse and eventually blend into the surrounding hot gas. A marked contrast to earlier simulations with static winds, where the cold gas mass could keep on growing via radiative cooling – whereas in these more realistic simulations, the expanding environment suppresses this growth.

The animation shows a slice through the mid-plane of one of our 3D cloud-crushing simulations in an expanding outflow. It shows how the initial cloud material mixes and moves in the wind.

A schematic demonstration of our novel cloud tracking scheme that enables the computational box to follow the cloud. This saves a lot of compute time and data processing required for these simulations and allows us to simulate cloud-wind interaction within the capabilities of our computational resources. © MPA, A. Dutta

Cloud expansion and pressure equilibrium are the key factors that regulate cold gas evolution. Even if initially a cloud would grow, it fades as it travels downstream, losing its ability to stand out from the background.

Moreover, the study finds that cold gas tails – common features seen in both simulations and observations – develop strong head-to-tail gradients in both density and brightness. This offers a natural explanation for recent high-resolution observations from the James Webb Space Telescope of intense star-forming galaxies like M82.

The key new feature to these simulations was a novel ‘cloud-tracking’ algorithm developed by the researchers, that allowed them to follow the cold gas for a long time/distance in an expanding wind without prohibitively expensive computational requirements. It is the first time, that such spatially expanding backgrounds have been self-consistently incorporated into cloud-crushing simulations – a crucial step towards bridging idealized theory and realistic galactic environments.

Looking ahead, the team plans to expand the simulations to include magnetic fields, thermal conduction, and more complex wind structures, like those relevant to active galactic nuclei (AGN) and cluster environments. This work is not just relevant for idealized simulations but has the potential to serve as the basis for building robust models of multiphase gas and their mixing on various scales, which is typically unresolved in cosmological simulations.

This work lays the foundation for a more complete theory of how galaxies lose – or retain – their fuel for star formation and that’s essential for understanding how galaxies live, grow, and die.




Contact:

Alankar Dutta
Tel: 2254
alankard@mpa-garching.mpg.de

Original publication

Alankar Dutta, Prateek Sharma, Max Gronke

Fading in the Flow: Suppression of cold gas growth in expanding galactic outflows
submitted to MNRAS


Source

More Information

Playlist of videos from the simulations
Codebase developed in this work on Github


Thursday, October 02, 2025

ALMA pinpoints the radio signature of planetary growth

Multi-frequency imaging of PDS 70 with .a zoom on the forming protoplanet PDS 70c. From left to right are the ALMA bands 4, 7, and 9. PDS70c shines in Bands 4 and 7, ,brbut not in Band 9, which can be attributed to ionized gas emission. Credit: O. Domínguez et al. – N. Lira – ALMA (ESO/NAOJ/NRAO)



New multi-frequency observations reveal that the growing giant planet PDS 70c shines in radio waves not from dust, but from ionized gas in its environment.

Highlights

  • Unprecedented multi-frequency radio observation of a forming planet: ALMA observed PDS 70c in Bands 3, 4, 7, and 9, revealing new details about its environment.
  • Not dusty, but gaseous: The radio signal originates from ionized gas, not from the dusty disk astronomers anticipated.
  • Likely origin in a circumplanetary disk: The emission most likely comes from the surface of a small disk surrounding the planet, where mass from the environment is deposited.
  • Clues to planet and moon formation: These findings present the first radio spectral fingerprint of a circumplanetary environment, offering insights into how giant planets develop and how moons may form.

Astronomers using the Atacama Large Millimeter/submillimeter Array (ALMA) have obtained an unprecedented multi-frequency view of a forming planet in the nearby star system PDS 70. The new study, led by postgraduate student MsOriana Domínguez-Jamett (Universidad de Chile) and published in Astronomy & Astrophysics, shows that the planet PDS 70c emits radio signals produced by ionized gas rather than the dusty disk expected around such a young world.

PDS 70, a young star 370 light-years away in the constellation Centaurus, is famous for hosting two directly imaged protoplanets. Among them, PDS 70c is thought to be surrounded by a circumplanetary disk — a disk of gas and dust feeding the planet and possibly forming moons. Until now, the exact origin of its radio emission remained a mystery.

Using new ALMA observations in Bands 4 (145 GHz), 7 (343.5 GHz), and 9 (671 GHz), together with archival Band 3 data (97.5 GHz), the team detected a compact source at the position of PDS 70c in three of the bands. Intriguingly, they found no signal in the highest frequencies (Band 9). This “drop” in brightness challenges the idea that the emission originates solely from thermal dust. Instead, the results are best explained by partially optically thick free-free emission — radio light generated by the collisions of electrons and ions. In simple terms, the radio light from PDS 70c mainly comes from the surface of a small disk surrounding the planet. This gaseous disk shines because its surface is ionized by the impact of infalling material, making it appear as a faint, glowing veil around the young planet.

“Our observations suggest that a standard dusty disk does not surround PDS 70c,” says lead author Oriana Domínguez-Jamett. “Instead, the signal points to ionized gas, possibly heated in shocks as material falls onto the planet’s disk. This means the planet is depleted of dust by at least a factor of a thousand compared to expectations.”

By comparing the spectrum with simple models, the researchers demonstrate that a very low ionization fraction can explain the observed turnover in emission. This marks the first time the radio emission mechanism in a circumplanetary environment has been identified.

“This is a breakthrough in our ability to study how gas giant planets grow and how their moons may form,” adds advisor Simon Casassus (Universidad de Chile). “ALMA can now not only detect circumplanetary disks but also determine what powers their emission.”

“These results highlight ALMA’s unique ability to probe the environment of forming planets,” says John Carpenter, ALMA Observatory Scientist. “By distinguishing between dust and gas emission, we gain a direct view of how young planets gather material and how future moon systems begin to form.”

The findings provide key new constraints on the density, temperature, and ionization state of the material around forming gas giants. They also highlight the unique potential of ALMA to explore the final stages of planet growth.

Additional Information

The results of this study appear in the Astronomy & Astrophysics as "Multi-frequency observations of PDS70c: Radio emission mechanisms in the circumplanetary environment" by O. Domínguez et al.

The Atacama Large Millimeter/submillimeter Array (ALMA), an international astronomy facility, is a partnership of the European Southern Observatory (ESO), the U.S. National Science Foundation (NSF), and the National Institutes of Natural Sciences (NINS) of Japan in cooperation with the Republic of Chile. ALMA is funded by ESO on behalf of its Member States, by NSF in cooperation with the National Research Council of Canada (NRC) and the National Science and Technology Council (NSTC) in Taiwan, and by NINS in cooperation with the Academia Sinica (AS) in Taiwan and the Korea Astronomy and Space Science Institute (KASI).

ALMA construction and operations are led by ESO on behalf of its Member States; by the National Radio Astronomy Observatory (NRAO), managed by Associated Universities, Inc. (AUI), on behalf of North America; and by the National Astronomical Observatory of Japan (NAOJ) on behalf of East Asia. The Joint ALMA Observatory (JAO) provides the unified leadership and management of ALMA's construction, commissioning, and operation.

Scientific Paper




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Wednesday, October 01, 2025

Yellow and blue, old and new

An oval-shaped spiral galaxy, of which only the centre and lower half is in frame. Its centre is mainly golden in colour with a white glowing core, while its thick spiral arms are mostly blue, particularly at the outskirts; the colours merge in between. Dark lanes of dust swirl through the centre, blocking some of its light. Stars and distant galaxies can be seen around the edges on a black background.Credit: ESA/Hubble & NASA, A. Filippenko - Acknowledgement: M. H. Özsaraç

Stars of all ages are on display in today’s NASA/ESA Hubble Space Telescope Picture of the Week. This sparkling spiral galaxy is called NGC 6000 and it is located 102 million light-years away in the constellation Scorpius.

This galaxy has a glowing yellow centre and glittering blue outskirts. The colours reflect differences in the average ages, masses and temperatures of the galaxy’s stars. In the heart of the galaxy, the stars tend to be older and smaller. Less massive stars are cooler than more massive stars, and somewhat counterintuitively, cooler stars are redder, while hotter stars are bluer. Farther out along NGC 6000’s spiral arms, brilliant star clusters host young, massive stars that appear distinctly blue.

Hubble collected the data for this image while surveying the sites of recent supernova explosions in nearby galaxies. NGC 6000 has hosted two recent supernovae: SN 2007ch in 2007 and SN 2010as in 2010. Using Hubble’s sensitive detectors, researchers are able to discern the faint glow of supernovae years after the initial explosion. These observations help to constrain the masses of supernova progenitor stars and can indicate if they had any stellar companions.

By zooming in to the right side of the galaxy’s disc in this image, you may see something else yellow and blue: a set of four thin lines. These are an asteroid in our Solar System, which was drifting across Hubble’s field of view as it gazed at NGC 6000. The four streaks are due to different exposures that were recorded one after another with slight pauses in between. These were combined to create this final image. The colours appear this way because each exposure used a filter to collect only very specific wavelengths of light, in this case around red and blue. Having these separate exposures is important to study and compare stars by their colours — but it also makes asteroid interlopers very obvious!



Spiral Galaxy NGC 5211


NGC 5211 is a face-on galaxy located in the direction of Virgo. Unlike typical spiral galaxies that have spiral arms connected directly to their central regions, this galaxy displays a gap between its central core and the arms, resulting in a ring-like structure known as a pseudoring. Additionally, a second ring-like spiral arm is also present in the central region, giving the unique appearance of a double-ring structure. The inner ring appears red, while the outer ring has a blue tint, creating a striking and contrasting visual impression. Credit: NAOJ; Image provided by Masayuki Tanaka

Distance from Earth: 180 million light-years
Instrument: Hyper Suprime-Cam (HSC)



Tuesday, September 30, 2025

Motion of Planet-Forming Spirals Captured on Video

ALMA observations of the spiral patterns in the disk around the young star
IM Lup. Credit: ALMA(ESO/NAOJ/NRAO), Tomohiro Yoshida et al.

Download image (3.6MB)

The Atacama Large Millimeter/submillimeter Array (ALMA) has captured the motion of spirals of dust around a young star and shown that the winding motion of the spiral pattern is conducive to planet formation. This provides new evidence for planet formation around this young star. The results could have implications for other young stars as well.

Observations have revealed a spiral pattern in the disk of gas and dust around the young star IM Lup located 515 light-years away in the direction of the constellation Lupus. Spiral patterns are thought to be one of the signs that a new planet will form soon, but other things, such as an already formed planet, can also form spirals. These different types of spirals cannot be distinguished by visual inspection, but they are expected to move differently over time.

To determine the origin of the spirals around IM Lup, an international research team led by Tomohiro Yoshida, a graduate student at The Graduate University for Advanced Studies, SOKENDAI and the National Astronomical Observatory of Japan (NAOJ), created a stop-motion animation of the spiral pattern using four observations taken by ALMA over the course of seven years. The motion of the spirals in the stop-motion animation shows that they were not caused by an already formed planet, and instead the spirals might be helping to form a new planet.

Tomohiro Yoshida says, “When I saw the outcome of the analysis —the dynamic visualization of the spiral in motion— I screamed with excitement. This achievement was made possible by the long-term, stable operations of the ALMA telescope, which demonstrates the world’s highest performance. In the future, we plan to conduct similar observations on other protoplanetary disks to create a documentary of the entire planetary system formation process.”

Video of artist’s impression of planet formation around a young star, showing spiral patterns which help the young planets to form. (Credit: ALMA(ESO/NAOJ/NRAO), Tomohiro Yoshida et al.)




Detailed Article(s)

Winding Motion of Planet-Forming Spirals Captured on Video for the First Time

ALMA



Release Information

Researcher(s) Involved in this Release
  • Tomohiro Yoshida (NAOJ/SOKENDAI)
  • Hideko Nomura (NAOJ/SOKENDAI)
  • Kiyoaki Doi (Max Planck Institute for Astronomy)
  • Marcelo Barraza-Alfaro (Massachusetts Institute of Technology)
  • Richard Teague (Massachusetts Institute of Technology)
  • Kenji Furuya (RIKEN)
  • Yoshihide Yamato (RIKEN)
  • Takashi Tsukagoshi (Ashikaga University)

Coordinated Release Organization(s)
  • National Astronomical Observatory of Japan
  • Massachusetts Institute of Technology
  • RIKEN
  • The Graduate University for Advanced Studies, SOKENDAI
  • Ashikaga University

Paper(s) Related Link(s)


Monday, September 29, 2025

Dwarf galaxies linked by massive intergalactic gas bridge

An image of the diffuse hydrogen emission seen by ASKAP overlaid with an optical image of the region.
Credit: ICRAR, N. Deg, Legacy Surveys (D.Lang / Perimeter Institute).

CSIRO’s ASKAP radio telescope on Wajarri Yamaji Country.
Credit: Alex Cherney/CSIRO

Left: Radio image of neutral hydrogen in and around NGC 4532 / DDO 137 using ASKAP. Right: an optical image of the galaxy from the Legacy Surveys. Credit: ICRAR and D.Lang (Perimeter Institute).




Astronomers have made a groundbreaking discovery of a colossal bridge of neutral hydrogen gas linking two dwarf galaxies.

Researchers from The University of Western Australia node at the International Centre for Radio Astronomy Research (ICRAR) have uncovered an immense structure, which spans an astonishing 185,000 light-years between galaxies NGC 4532 and DDO 137, located 53 million light-years from Earth.

The study, published overnight in the Monthly Notices of the Royal Astronomical Society, also revealed that a vast tail of gas accompanied the bridge, extending 1.6 million light-years, making it the longest-ever observed.

Lead author, ICRAR UWA astronomer Professor Lister Staveley-Smith, said the discovery marked a significant step forward in understanding how galaxies interact.

“Our modelling showed that the tidal forces acting between these galaxies, alongside their proximity to the massive Virgo cluster of galaxies, played a crucial role in the gas dynamics we observed,” Professor Staveley-Smith said.

“As the galaxies rotated around each other and moved toward the hot gas cloud surrounding the Virgo cluster, which was 200 times hotter than the Sun’s surface, they experienced what is known as ram pressure, which stripped and heated the gas from the galaxies.

“The process is akin to atmospheric burn-up when a satellite re-enters the Earth’s upper atmosphere, but has extended over a period of a billion years.

“The density of electrons and the speed at which galaxies are falling into the hot gas cloud are enough to explain why so much gas has been pulled away from the galaxies and into the bridge and surrounding areas.”

The observations were part of the Widefield ASKAP L-band Legacy All-sky Survey (WALLABY). This large-scale project maps the sky and studies the distribution of hydrogen gas in galaxies, using the ASKAP radio telescope, owned and operated by CSIRO, Australia’s national science agency.

Co-author and ICRAR UWA astrophysicist Professor Kenji Bekki said researchers discovered the colossal gas formations by using high-resolution observations of neutral hydrogen.

Neutral hydrogen plays a crucial role in the formation of stars, making this finding fundamental to understanding how galaxies interact and evolve, particularly in dense environments,” Professor Bekki said.

Professor Staveley-Smith said the system had strong similarities with our own Milky Way and Magellanic System, providing a unique opportunity to study such interactions in detail.

“Understanding these gas bridges and their dynamics provides critical insights into how galaxies evolve over time, how galactic gas is redistributed, and the varying conditions under which galaxies may or may not form stars,” he said.

“This contributes to our broader understanding of the most massive structures in the Universe and their life cycles, which helps us grasp more about their vast complexities and history of star formation.”




Publication:

WALLABY Pilot Survey: the extensive interaction of NGC 4532 and DDO 137 with the Virgo cluster

Multimedia: Download

Media Support:

For interview requests, please contact:

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Interviews

Professor Lister Staveley-Smith | ICRAR/UWA

Professor Kenji Bekki | ICRAR/UWA