This spectacular image from deep in the cosmos almost looks as if someone might have smudged it with their thumb.

But the effect is not from a human fingerprint, it is actually the result of a rare type of star and its companion locked in a celestial dance.

The intriguing sight of at least 17 dust rings was spotted by NASA‘s new James Webb Space Telescope (JWST).

Each ring was created when the two stars came close together and the streams of gas they blow into space collided, compressing the gas and forming dust. 

The orbit of the stars brings them together about once every eight years, and like the rings of a tree’s trunk, the dust loops mark the passage of time. 

Sitting more than 5,000 light years from Earth, the star and its companion are collectively known as Wolf-Rayet 140 (WR 140).

Peculiar: This spectacular image from deep in the cosmos looks like someone might have placed their finger on it and left behind a print. But the effect is not from a human, it is actually the result of a rare type of star and its companion locked in a celestial dance

Peculiar: This spectacular image from deep in the cosmos looks like someone might have placed their finger on it and left behind a print. But the effect is not from a human, it is actually the result of a rare type of star and its companion locked in a celestial dance

WHAT ARE WOLF-RAYET STARS?

Wolf-Rayet stars begin life as cosmic titans, with at least 25 times the mass of the sun. 

But they ‘live fast and die hard’, according to NASA, exploding as supernova and blasting vast amounts of heavy elements into space for use in later generations of stars and planets. 

And the majority of these brilliant but dying Wolf-Rayet stars have company – a smaller companion star orbiting nearby. 

Because Wolf-Rayet stars shed so much mass, they also eject more complex elements typically found deep in a star’s interior, including carbon. 

The heavy elements in the wind cool down as they travel into space and are then compressed where the winds from both stars meet, like when two hands knead dough.

Researchers say that while some other Wolf-Rayet systems form dust, none are known to make rings like Wolf-Rayet 140 does.

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Ryan Lau, an astronomer at the National Science Foundation’s NOIRLab, said: ‘We’re looking at over a century of dust production from this system.

‘The image also illustrates just how sensitive JWST is. Before, we were only able to see two dust rings, using ground-based telescopes. 

‘Now we see at least 17 of them.’

In addition to Webb’s overall sensitivity, the Mid-Infrared Instrument (MIRI) is uniquely qualified to study the dust rings, or what researchers call shells.

This is because it sees in infrared light, a range of wavelengths invisible to the human eye. 

By comparison, Webb’s predecessor – the iconic Hubble telescope – detects ultraviolet wavelengths as well as visible light.

The UK Astronomy Technology Centre (UK ATC) played a key role in designing and building MIRI’s spectrometer that was used to reveal the composition of the dust, formed mostly from the material ejected by the star which is a special type known as a Wolf-Rayet star.

This type of star is born with at least 25 times more mass than the Earth’s sun and is nearing the end of its life.

Burning hotter than in its youth, a Wolf-Rayet star generates powerful winds that push huge amounts of gas into space.

Experts believe the Wolf-Rayet star in this particular pair may have shed more than half its original mass via this process.

They say that transforming gas into dust is a bit like turning flour into bread – it requires specific conditions and ingredients.

Hydrogen, the most common element found in stars, cannot form dust on its own.

However, because Wolf-Rayet stars shed so much mass, they also eject more complex elements typically found deep in a star’s interior, including carbon.

The heavy elements in the wind cool down as they travel into space and are then compressed where the winds from both stars meet, like when two hands knead dough.

Researchers say that while some other Wolf-Rayet systems form dust, none are known to make rings like Wolf-Rayet 140 does.

The unique ring pattern forms because the orbit of the Wolf-Rayet star in WR 140 is elongated, not circular.

The intriguing sight of at least 17 dust rings - which resemble a fingerprint - was spotted by NASA's new James Webb Space Telescope (pictured)

The intriguing sight of at least 17 dust rings – which resemble a fingerprint – was spotted by NASA’s new James Webb Space Telescope (pictured) 

Only when the stars come close together – about the same distance between Earth and the sun – and their winds collide, is the gas under sufficient pressure to form dust.

The astronomers think WR 140’s winds also swept the surrounding area clear of residual material they might otherwise collide with, which could explain why the rings are so pristine.

Dr Olivia Jones, Webb Fellow at the UK ATC in Edinburgh, and a co-author of the study, said: ‘Not only is this a spectacular image but this rare phenomenon reveals new evidence about cosmic dust and how it can survive in the harsh space environments.

‘These kinds of discoveries are only now opening up to us through the power of Webb and MIRI.’

The findings are published in the journal Nature Astronomy.

The James Webb Telescope: NASA’s $10 billion telescope is designed to detect light from the earliest stars and galaxies

The James Webb telescope has been described as a ‘time machine’ that could help unravel the secrets of our universe.

The telescope will be used to look back to the first galaxies born in the early universe more than 13.5 billion years ago, and observe the sources of stars, exoplanets, and even the moons and planets of our solar system.

The vast telescope, which has already cost more than $7 billion (£5 billion), is considered a successor to the orbiting Hubble Space Telescope

The James Webb Telescope and most of its instruments have an operating temperature of roughly 40 Kelvin – about minus 387 Fahrenheit (minus 233 Celsius).

It is the world’s biggest and most powerful orbital space telescope, capable of peering back 100-200 million years after the Big Bang.

The orbiting infrared observatory is designed to be about 100 times more powerful than its predecessor, the Hubble Space Telescope.

NASA likes to think of James Webb as a successor to Hubble rather than a replacement, as the two will work in tandem for a while. 

The Hubble telescope was launched on April 24, 1990, via the space shuttle Discovery from Kennedy Space Centre in Florida.

It circles the Earth at a speed of about 17,000mph (27,300kph) in low Earth orbit at about 340 miles in altitude. 

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This post first appeared on Dailymail.co.uk

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