A thread of the cosmic web: astronomers spot a 50 million light-year galactic filament

2022. 12. 10. 16:58IndraNet.net/cosmic web

At the very largest scale, the Universe consists of a “cosmic web” made of enormous, tenuous filaments of gas stretching between gigantic clumps of matter. Or that’s what our best models suggest.



All we have seen so far with our telescopes are the stars and galaxies in the clumps of matter.


So is the cosmic web real, or a figment of our models? Can we confirm our models by detecting these faint gaseous filaments directly?


Until recently, these filaments have been elusive. But now a collaboration between Australian radio astronomers and German x-ray astronomers has detected one.


On the largest scales, matter in the Universe is arranged in a cosmic web consisting of filaments of gas separated by voids, with clusters where the filaments meet each other. From the MAGNETICUM simulation, courtesy of Klaus Dolag, Universitats-Sternwarte Munchen, Ludwig-Maximilians-Universitat Munchen, Germany


CSIRO’s newly completed Australian Square Kilometre Array Pathfinder (ASKAP) telescope in Western Australia is starting to produce a large-scale picture of the Universe in radio frequencies. This telescope can see deeper than any other radio telescope, producing new discoveries, such as the unexplained Odd Radio Circles or ORCs.


CSIRO's Australian Square Kilometre Array Pathfinder telescope in Western Australia. Ray Norris



Seeing with radio waves and x-rays


This year has also seen the publication of the first observations by the German eROSITA Space Telescope, which is giving us our deepest large-scale picture of the Universe in x-ray frequencies. Both of these next-generation telescopes have an unprecedented ability to scan large areas of sky at once, so they are beautifully matched to study the large-scale features of the Universe. Together, they can achieve much more than either on its own, so naturally we have joined forces.


The seven cameras of the eROSITA Space Telescope, enabling it to image the x-rays from large areas of the sky. Max Planck Institut for Extraterrestrial Physics


The first result from this collaboration is the discovery of a cosmic filament of hot gas. This study was led by Thomas Reiprich of the University of Bonn and Marcus Brueggen of the University of Hamburg, and involved Australian scientists from CSIRO and from Curtin, Macquarie, Monash and Western Sydney universities.


eROSITA image showing the clusters at the centre, and the dark green gaseous filament stretching 50 million light-years from the bottom left to the top right. Thomas Reiprich


The cosmic web


The Big Bang 13.8 billion years ago produced a Universe filled with invisible dark matter, together with a featureless gas of hydrogen and helium, and little else. Over the next few billion years, the gas clumped together under the attraction of gravity, forming filaments of matter with vast empty voids between them. The filaments probably contain more than half the matter in the Universe, even though the filaments themselves contain just ten particles per cubic metre - less than the best vacuum we can create on Earth.


Nearly all the galaxies we see today, including our own Milky Way, are thought to have formed in these filaments. We think galaxies then slide along the filaments until they fall into the dense clusters of galaxies clumped together at junctions where filaments meet.


This image, from a simulation called Magneticum, shows clumps moving along filaments, merging with the main systems to form ever larger, denser, and hotter structures. A movie is available at https://astro.uni-bonn.de/~reiprich/A3391_95/ . Thomas Reiprich (link to paper)


But until now, all this was hypothetical — we could see the galaxies and clusters, but we couldn’t see the gaseous filaments themselves. Now, eROSITA has directly detected the hot gas in a filament 50 million light-years long. This is an important step forward, confirming our model of the cosmic web is correct.



A smooth ride


We also expected the hot gas would whip up electrons to produce radio frequency emissions, but, curiously, we don’t detect the filament with ASKAP. This tells us the hot gas is flowing smoothly, without the turbulence that would accelerate electrons to produce radio waves. So the galaxies are getting a smooth ride as they fall into the clusters.


We can see the individual galaxies falling into the clusters in the radio images from ASKAP. At radio wavelengths, we often see galaxies bracketed by a pair of jets, caused by electrons squirting out from near the black hole in the centre of the galaxy.


However, in our radio images of these clusters, we see the jets bent and distorted as they are buffeted by intergalactic winds in the dense gas in the clusters. Again, this is a good confirmation of our models.


ASKAP radio data (white) overlaid on the eROSITA x-ray image (coloured). The circles show individual radio galaxies. The jets of the radio galaxies, normally straight, are bent into contorted shapes by the intergalactic winds within the clusters. Marcus Brueggen.

This work is not only important as confirmation of our model of the Universe, but is also the first result to come from the collaboration between ASKAP and eROSITA. These two telescopes are beautifully matched to survey our Universe, seeing the Universe as it has never been seen before, and I expect this discovery to be the first of many.




Ray Norris Professor, School of Science, Western Sydney University

Ray Norris is a British/Australian astronomer in the School of Science at Western Sydney University, and with CSIRO Astronomy & Space Science. He researches how galaxies formed and evolved after the Big Bang, and the process of astronomical discovery with large data volumes. He also researches the astronomy of Australian Aboriginal people.

Ray was educated at Cambridge University, UK, and moved to Australia in 1983 to join CSIRO, where he became Head of Astrophysics in 1994, and then Australia Telescope Deputy Director, and Director of the Australian Astronomy MNRF, before returning in 2005 to active research.

He currently leads an international project - the Evolutionary Map of the Universe - to image the faintest radio galaxies in the Universe, using the new ASKAP radio telescope recently completed in Western Australia. He also leads the WTF project which is exploring machine learning techniques to discover the unexpected.

He frequently appears on radio and TV, and has published a novel, Graven Images.

2016–present: Professor of Data Science in Astrophysics, Western Sydney University
1983–2014: Research scientist, CSIRO
2000–2005: Director, Australian Astronomy Major National Research Facility
2000–2005: Deputy Director, CSIRO Australia Telescope National Facility
1990–1999: Head of Astrophysics, CSIRO Australia Telescope National Facility

1979 University of Manchester, PhD
1977 University of Cambridge, MA