HiPERCAM used to reveal violent flaring at the heart of a black hole system

The state-of-the-art camera was developed by researchers at the University of Sheffield and can take more than 1,000 frames every second.

First photo using HiPERCAM - the spiral galaxy NGC 4800, which lies at a distance of 80 million light years
First light with HiPERCAM - the spiral galaxy NGC 4800, which lies at a distance of 80 million light years

An international team of astronomers, including academics from the University of Sheffield, have used state-of-the-art cameras to create a high frame-rate movie of an accreting black hole at a level of detail never seen before.

To capture the images they used HiPERCAM, a high-speed camera that can take more than 1,000 frames every second, which was developed by the University of Sheffield.

The resulting data allowed the team to study the immediate surroundings of the black hole.

Black holes can feed off a nearby star and create vast accretion discs of material. Here, the effect of the black hole’s strong gravity and the material’s own magnetic field can cause rapidly changing levels of radiation to be emitted from the system as a whole.

This radiation was detected in visible light by the HiPERCAM instrument on the Gran Telescopio Canarias (La Palma, Canary Islands) and in X-rays by NASA's NICER observatory aboard the International Space Station.

The black hole system studied is named MAXI J1820+070, and was first discovered in early 2018. It is only about 10,000 lightyears away, in our own Milky Way.

It has a mass of about seven suns, contained within a region of space smaller than the City of London.

Investigating these systems is usually very difficult, as their distances make them too faint and too small to see.

The HiPERCAM and NICER instruments however, let the researchers record ‘movies’ of the changing light from the system at over three hundred frames per second, capturing violent ‘flaring’ of visible and X-ray light.

Professor Vik Dhillon, from the University of Sheffield's Department of Physics and Astronomy, said: "The challenge with these observations was that we had to use extremely short exposure times - only a few milliseconds - on an extremely faint astronomical target.

“The combination of the high-speed camera, HiPERCAM, mounted on the world's largest optical telescope, the 10.4m Gran Telescopio Canarias (GTC) on La Palma, is the only facility in the world capable of providing such observations.”

Researchers found that dips in X-ray levels were accompanied by a rise in visible light and vice-versa, such patterns indirectly reveal the presence of distinct plasma, extremely hot material where electrons are stripped away from atoms, in structures deep in the embrace of the black hole’s gravity, otherwise too small to resolve.

John Paice, a graduate student at the University of Southampton and the Inter-University Centre for Astronomy and Astrophysics in India and lead author of the study, said: “The movie was made using real data, but slowed down to 1/10th of actual speed to allow the most rapid flares to be discerned by the human eye.

"We can see how the material around the black hole is so bright, it’s outshining the star that it is consuming, and the fastest flickers last only a few milliseconds – that’s the output of a hundred suns being emitted in the blink of an eye!

"Time-domain astrophysics is a research area rife with the potential of discovery, as this study demonstrates. New systems like MAXI J1820+070 are discovered every year.

"Novel cameras like HiPERCAM and NICER are helping us to better understand these enigmatic cosmic objects better than ever before.”

Artist's impression of the black hole system MAXI J1820+070, based upon observed characteristics during a rapid accretion episode in March 2018. Purple denotes X-ray radiation seen by the NICER instrument on the ISS and the rest of the colours are visibel
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