000006761 001__ 6761
000006761 005__ 20240205170703.0
000006761 100__ $$aVanlommel, Petra
000006761 245__ $$aSolar Orbiter Discovers Tiny Jets That Could Power the Solar Wind
000006761 260__ $$c2023
000006761 269__ $$c2023-08-24
000006761 500__ $$aRelated paper: https://www.science.org/doi/10.1126/science.ade5801
000006761 520__ $$aESA’s Solar Orbiter spacecraft has discovered a multitude of tiny jets of material escaping from the Sun’s outer atmosphere. Each jet lasts for between 20 and 100 seconds, and expels plasma at around 100 km/s. These jets could be the long-sought-after source of the ‘solar wind’. The solar wind consists of charged particles, known as plasma, that continuously escape the Sun. When the solar wind collides with Earth’s magnetic field, it produces the aurorae. Understanding how and where the solar wind is generated near the Sun has proven elusive and has been a key focus of study for decades. Now, observations by the Extreme Ultraviolet Imager (EUI) onboard Solar Orbiter have taken us an important step closer. EUI is a telescope observing the Sun in extreme ultraviolet light. It is operated by the Royal Observatory of Belgium, and its unprecedented high-resolution and high-cadence images of the Sun’s south pole on 30 March 2022 reveal a population of faint, short-lived features that are associated with small jets of million-degree plasma being ejected from the Sun’s atmosphere. The results are reported in a paper just published in the Science journal. Researchers have known for decades that a significant fraction of the solar wind is associated with magnetic structures called coronal holes – regions where the Sun’s magnetic field does not turn back down into the Sun. Instead, the magnetic field stretches deep into the Solar System. Plasma can flow along these ‘open‘ magnetic field lines. But the question was: how did the plasma get launched? The traditional assumption was that because the corona is hot, it will naturally expand and a portion of it will escape along the field lines, creating the solar wind. “One of our results is that to a large extent, this flow is not actually steady and uniform, as was traditionally assumed. Rather, the ubiquity of the jets suggests that the solar wind from coronal holes might originate as a highly intermittent outflow,” says Andrei Zhukov, Royal Observatory of Belgium, a collaborator on the work who led the Solar Orbiter observing campaign. The ubiquity of the tiny jets implied by the new observations suggests that they are expelling a substantial fraction of the material we see in the solar wind. And there could be even smaller, more frequent events providing yet more. “I think it's a significant step to find something on the solar disk that certainly is contributing to the solar wind,” says David Berghmans, Royal Observatory of Belgium, and principal investigator for the EUI instrument. In the next years, we expect EUI to register these tiny jets in a better perspective than now, as Solar Orbiter will gradually incline its orbit towards the polar regions. All involved will be eager to see what fresh insights they can collect because this work extends further than our own Solar System. The Sun is the only star whose atmosphere we can observe in such detail, but it is likely that the same process operates on other stars too. That turns these observations into the discovery of a fundamental astrophysical process.
000006761 594__ $$aSTCE
000006761 6531_ $$aSolar Orbiter
000006761 6531_ $$aEUI
000006761 6531_ $$acorona
000006761 6531_ $$aEUV
000006761 6531_ $$asolar wind
000006761 700__ $$aBerghmans, David
000006761 700__ $$aESA press team, X.
000006761 8560_ $$fdavid.berghmans@ksb-orb.be
000006761 85642 $$ahttps://www.stce.be/news/661/welcome.html
000006761 85642 $$ahttps://www.esa.int/Science_Exploration/Space_Science/Solar_Orbiter/Solar_Orbiter_discovers_tiny_jets_that_could_power_the_solar_wind
000006761 980__ $$aPRESSREL