News Release

Closest-ever approach to the sun gives new insights into the solar wind

Peer-Reviewed Publication

Imperial College London

Switchbacks Flythrough

video: Parker Solar Probe flew through several 'switchbacks' -- tubes of fast solar wind emerging from coronal holes in the sun's upper atmosphere. view more 

Credit: NASA

The Parker Solar Probe spacecraft, which has flown closer to the Sun than any mission before, has found new evidence of the origins of the solar wind.

NASA's Parker Solar Probe was launched in August 2018. Its first results are published today in a series of four papers in Nature, with Imperial College London scientists among those interpreting some of the key data to reveal how the solar wind is accelerated away from the surface of the Sun.

The solar wind is a stream of charged particles released by the Sun that fills our Solar System. It is responsible for the North and Southern lights, but can also cause disruption during violent episodes like solar flares and coronal mass ejections, knocking out power grids and satellites.

Now, an international team have shown that bursty 'spikes' of solar wind originate in holes in the Sun's outer atmosphere near its equator, and are accelerated by magnetic phenomena as they flow away into deep space and past the Earth.

The new research suggests that the spikes are generated by 'magnetic reconnection' near the Sun, a process that pulls on the tense lines of the Sun's magnetic field creates folds or 'switchbacks'. These events last only a couple of minutes but release lots of energy, accelerating the solar wind away in long tubes that are approximately the diameter of the Earth.

The finding builds on data from the HELIOS missions, launched in the 1970s, the previous record-holders for the closest approach to the Sun.

Professor Tim Horbury from Imperial's Department of Physics is a co-investigator on Parker Solar Probe's FIELDS instrument, which is led by the University of California, Berkeley. He said: "From HELIOS data we could see what might be 'spikes' of faster solar wind, and now we have been able to confirm their existence in striking detail with Parker Solar Probe.

"We usually think of the fast solar wind as very smooth, but Parker Solar Probe saw surprisingly slow wind with a large number of these little bursts and jets of plasma, creating long tubes of fast wind containing plasma with around twice the energy of the background solar wind."

Parker Solar Probe is studying the Sun's outer atmosphere, called the corona, directly flying through it to better understand the origins of the solar wind.

For the new study, Parker Solar Probe took data at a distance of 24 million kilometres from the Sun, inside the orbit of Mercury. It will fly successively closer to the Sun in the coming years, eventually reaching a distance of less than six million kilometres from its surface and far closer than the Earth's average distance of 150 million kilometres.

Scientists know the properties of the solar wind change as it travels from the Sun to the Earth, so studying the solar wind closer to its origin should reveal more about how it is created and evolves.

Parker Solar Probe will also be joined next year by Solar Orbiter, a European Space Agency mission with Imperial kit onboard.

Professor Horbury added: "Although Parker Solar Probe will get even more accurate measurements of the young solar wind at its closest approach, it's too close for telescopes, so it won't be able to see what features on the surface of the Sun may be creating the structures of the solar wind.

"This is where Solar Orbiter comes in. It will not go as close to the Sun, but will have sophisticated telescopes and instruments on board that will be able to see from a distance what might be causing phenomena Parker Solar probe is detecting up close, forming a fuller picture of what creates and accelerates the solar wind."

Other results from the first data include measurement of the speed the solar wind, which does not flow radially away from the Sun, but has a sideways speed of 15-25 times faster than predicted; and a 'snowplow' effect where charged particles bunch up before being accelerated by a coronal mass ejection event.

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