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A team mapping radio waves in the Universe has discovered something unusual that releases a giant burst of energy three times an hour, and it’s unlike anything astronomers have seen before.

The team who discovered it think it could be a neutron star or a white dwarf—collapsed cores of stars—with an ultra-powerful magnetic field.

Spinning around in space, the strange object sends out a beam of radiation that crosses our line of sight, and for a minute in every twenty, is one of the brightest radio sources in the sky.

An animation describing the discovery, the behaviour of the object and what it might look like. Credit: ICRAR.

Astrophysicist Dr Natasha Hurley-Walker, from the Curtin University node of the International Centre for Radio Astronomy Research, led the team that made the discovery.

“This object was appearing and disappearing over a few hours during our observations,” she said.

“That was completely unexpected. It was kind of spooky for an astronomer because there’s nothing known in the sky that does that.

“And it’s really quite close to us—about 4000 lightyears away. It’s in our galactic backyard.”

This image shows the Milky Way as viewed from Earth. The star icon shows the position of the mysterious repeating transient. Credit: Dr Natasha Hurley-Walker (ICRAR/Curtin).

This image shows the Milky Way as viewed from Earth. The star icon shows the position of the mysterious repeating transient. Credit: Dr Natasha Hurley-Walker (ICRAR/Curtin).

This image shows the Milky Way as viewed from Earth. The star icon shows the position of the mysterious repeating transient. Credit: Dr Natasha Hurley-Walker (ICRAR/Curtin).

This image shows a new view of the Milky Way from the Murchison Widefield Array, with the lowest frequencies in red, middle frequencies in green, and the highest frequencies in blue. The star icon shows the position of the mysterious repeating transient. Credit: Dr Natasha Hurley-Walker (ICRAR/Curtin) and the GLEAM Team.

The new radio transient in the sky, as it would have been seen at the MWA during the night in March 2018, when it was active. The source is shown with a large white star marker, but would be invisible to the naked eye. Image source: Stellarium

The new radio is transient in the sky, as it would have been seen at the MWA during the night in March 2018, when it was active. The source is shown with a large white star marker, but would be invisible to the naked eye. Image source: Stellarium

The location of the source in the sky in January 2022, marked with a large white star marker. At this time of year, it is above the horizon during the day. Image source: Stellarium

The location of the source in the sky in January 2022, marked with a large white star marker. At this time of year, it is above the horizon during the day. Image source: Stellarium

The object was discovered by Curtin University Honours student Tyrone O’Doherty using the Murchison Widefield Array (MWA) telescope in outback Western Australia and a new technique he developed.
“It’s exciting that the source I identified last year has turned out to be such a peculiar object,” said Mr O’Doherty, who is now studying for a PhD at Curtin.
“The MWA’s wide field of view and extreme sensitivity are perfect for surveying the entire sky and detecting the unexpected.”

Tile 107, or “the Outlier” as it is known, is one of 256 tiles of this SKA precursor instrument located 1.5km from the core of the telescope. Lighting the tile and the ancient landscape is the Moon. Photographed by Pete Wheeler, ICRAR.

Tile 107, or “the Outlier” as it is known, is one of 256 tiles of the MWA located 1.5km from the core of the telescope. The MWA is a precursor instrument to the SKA. Photographed by Pete Wheeler, ICRAR

Objects that turn on and off in the Universe aren’t new to astronomers—they call them ‘transients’.

ICRAR-Curtin astrophysicist and co-author Dr Gemma Anderson said that “when studying transients, you’re watching the death of a massive star or the activity of the remnants it leaves behind”.”

‘Slow transients’—like supernovae—might appear over the course of a few days and disappear after a few months.

‘Fast transients’—like a type of neutron star called a pulsar—flash on and off within milliseconds or seconds.

But Dr Anderson said finding something that turned on for a minute was really weird.

She said the mysterious object was incredibly bright and smaller than the Sun, emitting highly-polarised radio waves—suggesting the object had an extremely strong magnetic field.

A team mapping radio waves in the Universe has discovered something unusual that releases a giant burst of energy three times an hour, and it’s unlike anything astronomers have seen before. An animation showing the emission profile of the radio source. Credit: Dr Natasha Hurley Walker (ICRAR/Curtin) and the GLEAM Team.

Dr Hurley-Walker said the observations match a predicted astrophysical object called an ‘ultra-long period magnetar’.

“It’s a type of slowly spinning neutron star that has been predicted to exist theoretically,” she said.

“But nobody expected to directly detect one like this because we didn’t expect them to be so bright.

“Somehow it’s converting magnetic energy to radio waves much more effectively than anything we’ve seen before.”

Magnetar An artist’s impression of a what the object might look like if it’s a magnetar. Magnetars are extremely magnetic neutron stars, some of which sometimes produce radio emission. Known magnetars rotate every few seconds, but theoretically "ultra-long period magnetars" could rotate much more slowly. Credit: ICRAR.

Magnetar
An artist’s impression of what the object might look like if it’s a magnetar. Magnetars are incredibly magnetic neutron stars, some of which sometimes produce radio emission. Known magnetars rotate every few seconds, but theoretically, “ultra-long period magnetars” could rotate much more slowly. Credit: ICRAR.

In this video, lead researcher Dr Natasha Hurley-Walker from the Curtin University node of the International Centre for Radio Astronomy Research answers some questions about the discovery. Credit: ICRAR.

Dr Hurley-Walker is now monitoring the object with the MWA to see if it switches back on.

“If it does, there are telescopes across the Southern Hemisphere and even in orbit that can point straight to it,” she said.

Dr Hurley-Walker plans to search for more of these unusual objects in the vast archives of the MWA.

“More detections will tell astronomers whether this was a rare one-off event or a vast new population we’d never noticed before,” she said.

MWA Director Professor Steven Tingay said the telescope is a precursor instrument for the Square Kilometre Array—a global initiative to build the world’s largest radio telescopes in Western Australia and South Africa.

“Key to finding this object, and studying its detailed properties, is the fact that we have been able to collect and store all the data the MWA produces for almost the last decade at the Pawsey Research Supercomputing Centre. Being able to look back through such a massive dataset when you find an object is pretty unique in astronomy,” he said.

“There are, no doubt, many more gems to be discovered by the MWA and the SKA in coming years.”

Tape storage at the Pawsey Supercomputing Research Centre was used to store and share the data used by this project. Credit: Pawsey Supercomputing Research Centre.

Tape storage at the Pawsey Supercomputing Research Centre was used to store and share the data used by this project. Credit: Pawsey Supercomputing Research Centre.

The Pawsey Supercomputing Research Centre houses the systems used to process the data for this project. In this image, Garrawarla, a dedicated system to MWA researchers. Credit: Pawsey Supercomputing Research Centre.

The Pawsey Supercomputing Research Centre houses the systems used to process the data for this project. In this image, Garrawarla, a dedicated system to MWA researchers. Credit: Pawsey Supercomputing Research Centre.

Composite image of the SKA-Low telescope in Western Australia. The image blends a real photo (on the left) of the SKA-Low prototype station AAVS2.0 which is already on-site, with an artist’s impression of the future SKA-Low stations as they will look when constructed. These dipole antennas, which will number in their hundreds of thousands, will survey the radio sky at frequencies as low as 50Mhz. Credit: ICRAR, SKAO.

Composite image of the SKA-Low telescope in Western Australia. The image blends a real photo (on the left) of the SKA-Low prototype station AAVS2.0 which is already on-site, with an artist’s impression of the future SKA-Low stations as they will look when constructed. These dipole antennas, which will number in their hundreds of thousands, will survey the radio sky at frequencies as low as 50Mhz. Credit: ICRAR, SKAO.

The Murchison Widefield Array is located on the Murchison Radio-astronomy Observatory in Western Australia. The observatory is managed by CSIRO, Australia’s national science agency, and was established with the support of the Australian and Western Australian Governments. We acknowledge the Wajarri Yamatji as the traditional owners of the observatory site.

The Pawsey Supercomputing Research Centre in Perth–a Tier 1 publicly funded national supercomputing facility–helped store and process the MWA observations used in this research.

Shanghai Astronomical Observatory (SHAO) is a member of the MWA. China’s SKA Regional Centre Prototype, funded by the Ministry of Science and Technology of China and the Chinese Academy of Sciences, is hosted by SHAO and contributed to processing the MWA observations used in this research.

PublicATION

‘A radio transient with unusually slow periodic emission’, published in Nature on January 27th, 2022.

Supporting Multimedia

You are welcome to use any of these images in press articles or on social media, with the credit line intact.

Interviews:

Dr Natasha Hurley-Walker | ICRAR / Curtin University | Natasha.Hurley-Walker@curtin.edu.au

Tyrone O’Doherty | ICRAR / Curtin University | tyrone.odoherty@postgrad.curtin.edu.au

Dr Gemma Anderson | ICRAR / Curtin University | gemma.anderson@curtin.edu.au

Dr Xiang Zhang | Shanghai Astronomical Observatory | xiang.zhang@shao.ac.cn

MEDIA Enquiries:

Pete Wheeler | ICRAR | Pete.Wheeler@icrar.org | +61 423 982 018
Lucien Wilkinson | Curtin University | Lucien.Wilkinson@curtin.edu.au | +61 401 103 683