Space samples suggest ‘new physics’ in cause of violent solar flares

Despite posing a danger to technology on Earth, little is known about what causes huge coronal mass ejections

Harry Cockburn
Monday 17 February 2020 16:42 GMT
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A large coronal mass ejection such as the one which hit Earth in 1859, would have a major impact on power and communications technology infrastructure
A large coronal mass ejection such as the one which hit Earth in 1859, would have a major impact on power and communications technology infrastructure

Every day, huge explosions on the Sun erupt with massive amounts of energy, flinging particles out into space.

These events, called coronal mass ejections, largely made up of hydrogen particles, tear through the solar system at speeds of around 2 million miles per hour – this is also known as solar wind.

It is these particles interacting with the magnetic field of the Earth, which is most concentrated at its poles, which cause the shimmering colours of the aurora borealis and aurora australis – the northern and southern lights.

Coronal mass ejections vary in ferocity, and the Sun goes through cycles of heightened and reduced activity.

A powerful flare has the capacity to severely disrupt radio transmissions and cause damage to satellites and electrical transmission line facilities, resulting in potentially massive and long-lasting power outages.

Despite the beauty and the danger coronal mass ejections present, their cause is pretty much a mystery.

But a new study has measured the various levels and ratios of the elements the Sun fires out into space when a coronal mass ejection occurs, and provides new insight into the underlying physics in the Sun that causes these flares.

The study, led by researcher Gary Huss at the University of Hawaii at Mānoa has helped refine understanding of the amount of hydrogen, helium, neon and other elements present in the violent eruptions.

The team investigated a sample of solar wind particles collected by Nasa’s Genesis mission, which returned to Earth in 2004. Genesis was the first spacecraft to return material from beyond the orbit of the Moon.

Most of our understanding of the composition of the sun, which makes up 99.8 per cent of all mass in the Solar System, has come from astronomical observations and measurements of a rare type of meteorite.

But the Genesis samples allowed for a more accurate assessment of the hydrogen abundance in solar flares and other components of the solar wind. About 91 per cent of the Sun’s atoms are hydrogen, so everything that happens in the solar wind plasma is influenced by hydrogen.

The team said measuring hydrogen in the Genesis samples proved to be a challenge. An important part of the recent work was to develop new standards for hydrogen measurement by examining terrestrial minerals with known amounts of hydrogen, implanted with hydrogen by a laboratory particle accelerator.

A precise determination of the amount of hydrogen in the solar wind allowed researchers to discern small differences in the amount of neon and helium relative to hydrogen ejected by these massive solar ejections.

Helium and neon, both noble gases, and therefore very stable, are difficult to ionize – to change the number of electrons in each atom.

But the new measurements of hydrogen in the Genesis samples revealed that helium and neon were both enriched during coronal mass ejections. The team said the discovery provides new clues to the underlying physics in the Sun causing coronal mass ejections.

During these explosive reactions “the ejected material appears to be enriched almost systematically in atoms that require the most energy to ionize,” said Ryan Ogliore, co-author and assistant professor of physics at Washington University in St Louis.

“That tells us a lot about the physics involved in the first stages of the explosion on the Sun.”

The finding brings scientists closer to understanding the origins of these violent solar events.

The research is published in the Wiley Online Library.

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