@adamfinley
ESA Research Fellow at ESTEC in the Netherlands. Investigating the Sun's magnetic activity, solar wind connection science, and the spin-down of Sun-like stars. Previously a postdoc at CEA Paris-Saclay and PhD at Uni of Exeter.
It's paper time ! π
The article got accepted yesterday and is now available on arXiv, thread presenting the main results below ! β¨
arxiv.org/abs/2603.01979
βοΈ #stellarastro
Image from ESA's Solar Orbiter (EUI/FSI) of an S-shaped coronal hole, stretching from bottom left to top right. We are attempting to capture the sources of the fast solar wind detected insitu at the spacecraft with high resolution imagery and spectroscopy. Supported by Hinode and IRIS. βοΈππ¨
Visiting @sy-brt.bsky.social et al. at the Catania observatory where we discussed the activity of Sun-like stars and the links between ESA's Solar Orbiter and PLATO missions. After a few stormy days, I finally made it to the observatory for sunny views of Etna ποΈ and a look at the solar telescope βοΈ
Ever wondered what powers a solar flare? π₯
Solar Orbiter is finally giving us answers to this long-standing mystery.
The mission caught a 'magnetic avalanche' on the surface of the Sun just before a flare was released.
ππ§ͺ1/3
Are you (or do you know of) an undergrad with an interest in solar physics? Check out the Leiden/ESA Astrophysics Program for Summer Students (LEAPS 2026). Myself, Andy To and Henrik Eklund invite you to come work with us at ESTEC on "Catching the Solar Wind in Action". leaps.strw.leidenuniv.nl#none
New paper day! π₯ George Cherry et al. use the Most Significant Frequency decomposition to investigate shocks, jets, and swirls in the Sun's atmosphere. We find the contribution of 3.5 and 5 mHz signals to be up to 50% of the
overall wave power. Published in A&A: www.aanda.org/articles/aa/...
Blue Origin: Engineer becomes first wheelchair user to go to space
π Until now, observing the inner regions of the Sunβs enigmatic atmosphere β the corona β was close to impossible.
π°οΈπ°οΈβοΈ The satellite duo making up @esa.intβs Proba-3 mission fills this observation gap by creating artificial solar eclipses in orbit π www.esa.int/Enabling_Sup...
2025 was a landmark year for Europe in space π
From celebrating 50 years of ESA to new missions and scientific breakthroughs, the year reaffirmed Europeβs leadership in science, exploration, climate action and innovation.
π₯ Watch our highlights video:
youtu.be/obJbRWZ8f1Y?...
π£ New outreach poster: ESAβs Vigil Mission βοΈπ¨π°οΈπ¨π
The Space-weather βreporterβ will monitor the Sun from the Lagrange point 5, reporting 24/7 solar activity days before it reaches Earth.
www.esa.int/var/esa/stor...
Black disk surrounded by a greenish solar corona
Yellow Sun surrounded by a greenish disk of solar corona surrounded by a bigger reddish disk of solar corona
π°οΈπ€©π The #Proba-3 satellite duo, creators of #solareclipses, have just celebrated their first anniversary in space! The multitude of images already provided by #ASPIICS on board is a source of great joy for the Royal Observatory of Belgium, its principal investigator. www.astro.oma.be/en/...
Published in @aanda-journal.bsky.social π: www.aanda.org/articles/aa/...
βοΈFlying through the strongest solar storm ever recorded
No communication or navigation, faulty electronics, collision risks. ESA mission control teams faced a scenario unlike any before. Fortunately, this nightmare unfolded not in reality, but as part of the simulation!
www.esa.int/Space_Safety...
Comparison at the time of Orbiter:
Beautiful double erruption in 304A observed by GOES/SUVI and Solar Orbiter over the east-limb (slightly later) in the low-latency data.
Photograph of the bottom half of the Sun, with a highlighted square region around the Sun's south pole. Taken in ultraviolet light, the image shows the hot gas in the Sun's outer atmosphere, the corona, glowing yellow as it extends outwards in threads and loops from the Sun. Credit: ESA & NASA/Solar Orbiter/EUI Team, D. Berghmans (ROB)
Are you an early-career scientist or engineer?
Then the ESA Research #Fellowships in Space Science might be just the right opportunity for you.
Check out the programme details here π www.cosmos.esa.int/web/space-sc... π π§ͺ βοΈ
The AlfvΓ©n radius is linked to the solar wind mass and magnetic flux. The wind magnetisation parameter (~ratio of mag/mass flux), is used to understand this dependence. Our results follow the trends from MHD wind simulations, but had an offset that is likely due to 3D effects and turbulence. (5/8)
Towards maximum activity, the heliospheric current sheet became complex and the solar wind sources moved towards the active latitudes. So, for example, an encounter of PSP that spends more time in the solar wind near current sheets will have a smaller AlfvΓ©n radii on average. (7/8)
A very dipolar magnetic field became inclined to the rotation axis. (6/8)
The heliospheric current sheet became warped by the emergence of active regions. (5/8)
The evolution of the coronal magnetic field during the solar cycle, strongly influenced the magnetic connectivity of PSP. Each encounter is different, which obscures our perception of the average AlfvΓ©n radius. Near minimum, the wind measured by PSP originated closer to the Sun's poles. (4/8)
We mapped the wind back to its source using the Parker spiral and a potential field source surface model. The AlfvΓ©n surface was modulated by structure in the corona. Smaller near current sheets and pseudo-streamers, larger near the dipole axis and expanding magnetic field. (3/8)
Using hourly measurements from the SWEAP and FIELDS suites, we mapped PSP to the AlfvΓ©n surface with a Parker spiral. Each encounter had a distribution of radii. The longitudinal-average reduced the bias from individual wind streams, the average grew from 10-16 solar radii. (2/8)
Side project day! NASA's Parker Solar Probe (PSP) has been exploring the near-Sun enviroment since the start of solar cycle 25. Now passing maximum activity, how has the shape and size of the Sun's AlfvΓ©n surface evolved since? arxiv.org/abs/2509.07088 (1/8)
New paper day! Metcalfe et al. review the evidence for weakened magnetic braking around the Sun's age by homogenizing the stellar parameters from previous studies that constrained the wind braking of stars with observed magnetic fields and x-ray fluxes (proxy for mass-loss): arxiv.org/pdf/2509.03717
3D view of this plot:
Approaching perihelion (16th Sept.), the structure of the coronal magnetic field is similar to our prediction from July. The Sun's dipole field remains fully inclined with nested active regions influencing the heliospheric current sheet. Solar Orbiter will be mostly connnected to active latitudes.
ESA Solar Orbiter is zooming towards the Sun (perihelion at 0.29au on the 16th Sept.), currently at 0.44au the spacecraft has a nice view of the south pole (combined image from EUI/FSI). Coronal holes, filaments, active regions, lots of things to investigate!
Infographic showing how the Solar Orbiter spacecraft traces superfast electrons back to their sources on the Sun. The Sun is depicted on the left, with colored dots representing sources of energetic electrons from solar flares (blue) and coronal mass ejections (red). Curved lines illustrate magnetic field lines along which electrons travel from these events toward the Solar Orbiter spacecraft, shown on the right against a starry background. Text explains that more than 300 bursts of 'Solar Energetic Electrons' were observed between November 2020 and December 2022, allowing scientists to connect electrons detected in space with their origins on the Sun.
Our #SolarOrbiter has split the flood of energetic electrons flung out into space from the Sun into two groups, tracing each back to a different kind of outburst from our star π www.esa.int/Science_Expl...
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