Most detailed-ever images of galaxies revealed using LOFAR

A compilation of the science results. Credit from left to right starting at the top: N. Ramírez-Olivencia et el. [radio]; NASA, ESA, the Hubble Heritage Team (STScI/AURA)-ESA/Hubble Collaboration and A. Evans (University of Virginia, Charlottesville/NRAO/Stony Brook University), edited by R. Cumming [optical], C. Groeneveld, R. Timmerman; LOFAR & Hubble Space Telescope,. Kukreti; LOFAR & Sloan Digital Sky Survey, A. Kappes, F. Sweijen; LOFAR & DESI Legacy Imaging Survey, S. Badole; NASA, ESA & L. Calcada, Graphics: W.L. Williams.

After almost a decade of work, an international team of astronomers has published the most detailed images yet seen of galaxies beyond our own, revealing their inner workings in unprecedented detail. The images were created from data collected by the Low Frequency Array (LOFAR), a radio telescope built and maintained by ASTRON, LOFAR is a network of more than 70,000 small antennae spread across nine European counties, with its core in Exloo, the Netherlands. The results come from the team’s years of work, led by Dr Leah Morabito at Durham University. The team was supported in the UK by the Science and Technology Facilities Council (STFC).

As well as supporting science exploitation, STFC also funds the UK subscription to LOFAR including upgrade costs and operation of its LOFAR station in Hampshire.

Revealing a hidden universe of light in HD

The universe is awash with electromagnetic radiation, of which visible light comprises just the tiniest slice. From short-wavelength gamma rays and X-rays, to long-wavelength microwave and radio waves, each part of the light spectrum reveals something unique about the universe. The LOFAR network captures images at FM radio frequencies that, unlike shorter wavelength sources like visible light, are not blocked by the clouds of dust and gas that can cover astronomical objects. Regions of space that seem dark to our eyes, actually burn brightly in radio waves – allowing astronomers to peer into star-forming regions or into the heart of galaxies themselves.

The new images, made possible because of the international nature of the collaboration, push the boundaries of what we know about galaxies and super-massive black holes. A special issue of the scientific journal Astronomy & Astrophysics is dedicated to 11 research papers describing these images and the scientific results.

Better resolution by working together

The images reveal the inner-workings of nearby and distant galaxies at a resolution 20 times sharper than typical LOFAR images. This was made possible by the unique way the team made use of the array.

The 70,000+ LOFAR antennae are spread across Europe, with the majority being located in the Netherlands. In standard operation, only the signals from antennae located in the Netherlands are combined, and creates a ‘virtual’ telescope with a collecting ‘lens' with a diameter of 120 km. By using the signals from all of the European antennae, the team have increased the diameter of the ‘lens’ to almost 2,000 km, which provides a twenty-fold increase in resolution.

Unlike conventional array antennae that combine multiple signals in real time to produce images, LOFAR uses a new concept where the signals collected by each antenna are digitised, transported to central processor, and then combined to create an image. Each LOFAR image is the result of combining the signals from more than 70,000 antennae, which is what makes their extraordinary resolution possible.

This shows real radio galaxies from Morabito et al. (2021). The gif fades from the standard resolution to the high resolution, showing the detail we can see by using the new techniques. Credit: L.K. Morabito; LOFAR Surveys KSP.

Revealing jets and outflows from super-massive black holes

Super-massive black holes can be found lurking at the heart of many galaxies and many of these are ‘active’ black holes that devour in-falling matter and belch it back out into the cosmos as powerful jets and outflows of radiation. These jets are invisible to the naked eye, but they burn bright in radio waves and it is these that the new high-resolution images have focused upon.

Dr Neal Jackson of The University of Manchester, said: “These high resolution images allow us to zoom in to see what’s really going on when super-massive black holes launch radio jets, which wasn’t possible before at frequencies near the FM radio band,”

The team’s work forms the basis of nine scientific studies that reveal new information on the inner structure of radio jets in a variety of different galaxies.

Hercules A is powered by a supermassive black hole located at its centre, which feeds on the surrounding gas and channels some of this gas into extremely fast jets. Our new high-resolutions observations taken with LOFAR have revealed that this jet grows stronger and weaker every few hundred thousand years. This variability produces the beautiful structures seen in the giant lobes, each of which is about as large as the Milky Way galaxy. Credit: R. Timmerman; LOFAR & Hubble Space Telescope

A decade-long challenge

Even before LOFAR started operations in 2012, the European team of astronomers began working to address the colossal challenge of combining the signals from more than 70,000 antennae located as much as 2,000 km apart. The result, a publicly-available data-processing pipeline, which is described in detail in one the scientific papers, will allow astronomers from around the world to use LOFAR to make high-resolution images with relative ease.

Dr Leah Morabito of Durham University, said: “Our aim is that this allows the scientific community to use the whole European network of LOFAR telescopes for their own science, without having to spend years to become an expert.”

Super images require supercomputers

The relative ease of the experience for the end user belies the complexity of the computational challenge that makes each image possible. Because LOFAR doesn’t just ‘take pictures’ of the night sky, it must stitch together the data gathered by more than 70,000 antennae, which is a huge computational task. To produce a single image, more than 13 terabits of raw data per second – the equivalent of more than a three hundred DVDs – must be digitised, transported to a central processor and then combined.

Frits Sweijen of Leiden University, said: “To process such immense data volumes we have to use supercomputers. These allow us to transform the terabytes of information from these antennas into just a few gigabytes of science-ready data, in only a couple of days.”

Media

All images and video's belonging to this press release can be found in high resolution here.

Links to Arxiv (free) papers can be found here.

About LOFAR

The International LOFAR Telescope is a trans-European network of radio antennas, with a core located in Exloo in the Netherlands. LOFAR works by combining the signals from more than 70,000 individual antenna dipoles, located in ‘antenna stations’ across the Netherlands and in partner European countries. The stations are connected by a high-speed fibre optic network, with powerful computers used to process the radio signals in order to simulate a trans-European radio antenna that stretches over 1,300 kilometres. The International LOFAR Telescope is unique, given its sensitivity, wide field-of-view, and image resolution or clarity. The LOFAR data archive is the largest astronomical data collection in the world.

LOFAR was designed, built and is presently operated by ASTRON, the Netherlands Institute for Radio Astronomy. France, Germany, Ireland, Italy, Latvia, the Netherlands, Poland, Sweden and the UK are all partner countries in the International LOFAR Telescope.

Source: ASTRON/News

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C'est magnifique: LOFAR goes multi-national

This image shows radio sources in the wide field surrounding 3C196, which is the bright spot at the center of the image. (high resolution image)

This image hows the blow-up of 3C196 from the previous image. Made with the Dutch baselines only, the smallest detail seen in this image is 265 thousand light years across and 3C196 appears as a single source.

This image made with the Dutch and the international baselines offers an increase of 30 fold in resolution. The quasar 3C196 is seen to consist of two slightly extended components with the smallest detail in the image being 7 thousand light years.

Image credits of the above images: multi-national LOFAR commissioning teams led by Olaf Wucknitz (Argelander Institut für Astronomie, University of Bonn, Germany) and Reinout van Weeren (Leiden Observatory, University of Leiden).

For the first time, the signals from antenna stations of the giant radio telescope LOFAR in the Netherlands, France, Germany, and the United Kingdom have been simultaneously combined together in the LOFAR BlueGene/P supercomputer. This achievement makes the International LOFAR Telescope (ILT), an array with both excellent sensitivity, thanks to the 40 Dutch stations at the heart of the array, and excellent resolving power, thanks to its European dimensions out to 1000 km.

LOFAR, the Low Frequency Array, was built by ASTRON in the Netherlands. It is currently being extended to European dimensions with partners in France, Germany, Sweden, and the United Kingdom (the Swedish station awaits completion later this year). Combining the Dutch and international LOFAR signals together is an important milestone that truly unites the various stations into a new and powerful facility - the ILT.

The new capabilities now realized, are demonstrated in an amazing sequence of low-frequency images of the bright radio quasar 3C196, located in a galaxy so distant that light takes 6.9 billion years to reach the Earth. This sequence shows the huge field of view that can be uniquely captured by LOFAR and covers an area of the sky equivalent to a staggering 1000 full moons, revealing a stunning variety of objects, surrounding 3C196. Some individual celestial objects may appear rather compact when viewed with the LOFAR core in the Netherlands alone. Now, with the combined multi-national resolving power of the ILT, the structure of such distant objects can be revealed with a resolution as fine as 0.2 arcseconds, close to 1/10000 of the diameter of the full moon.

ILT Director Dr. René Vermeulen of ASTRON is delighted with the news: "Years of design and development work have led to this great achievement. We now have fantastic evidence of the full potential of this revolutionary new telescope, which is drawing great interest from the astronomical community all across Europe, and beyond. Their research interests start in the upper reaches of Earth's atmosphere, and go right out to the furthest and youngest parts of the Universe. Our first multi-national result will cement an already close international collaboration of all partners in the ILT".

For more information, please contact:

Dr. René Vermeulen, director of the International LOFAR Telescope (ILT). Tel.: +31 521 595 100. E-mail: rvermeulen@astron.nl

Femke Boekhorst, PR & Communication, ASTRON. Tel.: +31 521 595 204. E-mail: boekhorst@astron.nl


About LOFAR

The International LOFAR telescope is a Pan-European collaborative project led by ASTRON Netherlands Institute for Radio Astronomy. Combining thousands of simple dipole receivers with powerful digital signal processing and high-performance computing, LOFAR can rapidly survey wide areas of the sky, looking in multiple directions simultaneously and relatively unexplored low frequencies, opening open up a new window for astronomers.


LOFAR will focus on six areas of research:


1. The Epoch of Reionisation - understanding how the first stars and black holes made the universe hot.
2. Extragalactic surveys - what is the history of star formation and black hole growth over cosmological time?
3. Transients and Pulsars - probing the extreme astrophysical environments that lead to transient bright bursts in the radio sky.
4. Cosmic rays - what is the origin of the most energetic particles in the universe?
5. Solar and space environment - mapping the structure of the solar wind, how it relates to solar bursts, and how it interacts with the Earth.
6. Cosmic Magnetism - what is the origin of the large-scale magnetic fields that pervade the universe?

The quasar galaxy 3C 196

3C 196 is a quasar (compact radio source) in a galaxy so far away that light from it has travelled for almost half the age of the universe to reach us (at a redshift of z=0.871). The word "quasar" means "quasi-stellar object". Quasars look like single stars in visible light because the light coming from close to the central black hole is so bright that it outshines all the stars in the galaxy in which it is embedded. The quasar 3C 196 was picked for the first light image of the LOFAR Telescope to show the massive increase in image sharpness (resolution) when the international stations are added to LOFAR.