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The Sun\u2019s inner corona, the hottest part of our star’s atmosphere, appears faint yellow in this time-lapse made from images taken by the ASPIICS coronagraph aboard Proba-3.<\/p>\n
The European Space Agency\u2019s Proba-3 mission consists of two spacecraft capable of flying in precisely controlled formation to create artificial solar eclipses in orbit.<\/p>\n
This animation combines data from Proba-3\u2019s ASPIICS coronagraph (inner solar corona in yellow) and from the Atmospheric Imaging Assembly (AIA) aboard NASA\u2019s Solar Dynamics Observatory (solar disc in dark orange).<\/p>\n
\u201cThe corona is extremely hot, about two hundred times hotter than the Sun’s surface,\u201d explains Andrei Zhukov from the Royal Observatory of Belgium, Principal Investigator for ASPIICS.<\/p>\n
\u201cSometimes, structures made of relatively cold plasma (charged gas) are observed near the Sun \u2013 although these are still around 10\u00a0000 degrees, they are much colder than the surrounding million-degree hot corona \u2013 creating what we call \u2018a\u00a0prominence\u2019.\u201d<\/p>\n
Prominences can expand outwards from the Sun and \u2018erupt\u2019, breaking up and sending plasma in different directions.<\/p>\n
This animation resulted from ASPIICS observing the Sun during an active period on 21 September 2025, with one image taken every five minutes, capturing three prominence eruptions in five hours.<\/p>\n
\u201cSeeing so many prominence eruptions in such a short timeframe is rare, so I\u2019m very happy we managed to capture them so clearly during our observation window,\u201d adds Andrei.<\/p>\n
The ASPIICS instrument captures the solar corona with several filters, including two different \u2018spectral lines\u2019, each line corresponding to a different element contained in the coronal gases.<\/p>\n
The prominence eruptions seen in this animation were captured in the spectral line emitted by helium atoms, showing the solar atmosphere similarly to how a human eye would see it during a total eclipse through a yellow ASPIICS filter. The AIA image shows the emission in another spectral line produced by helium.<\/p>\n
The remaining faint yellow glow of the corona is a result of the scattering of visible light from the Sun’s surface on coronal electrons.<\/p>\n
A set of onboard positioning technologies allow the Proba-3 satellite duo to create solar eclipses in orbit. Thanks to this, the mission is able to observe the inner section of the Sun\u2019s corona, providing scientists with the puzzle piece that has so far been missing from consistent solar observations.<\/p>\n
[Image description: This is a gif animation made up of false-colour images taken by ESA\u2019s Proba-3 mission and NASA\u2019s Solar Dynamics Observatory. Against a dark background, the Sun\u2019s disc is shown in dark orange, as captured by NASA\u2019s Solar Dynamics Observatory. A thin halo of yellow light surrounds the Sun, giving it a luminous outline against the dark background of space. This yellow outline shows the Sun\u2019s inner corona, as captured by Proba-3. Also in yellow, three solar prominence eruptions are visible, resembling bright yellow wave-like outburst extending outwards from the Sun. First, we can see a smaller one in the top right corner, followed by a larger one in the top left and a third one in the bottom right. The whole animation lasts about 4 seconds and plays in a loop.]<\/i><\/p>\n<\/p><\/div>\n<\/p><\/div>\n