A breakthrough in solar physics now explains how dense clumps of plasma condense and fall through the Sun’s corona during powerful flares — behaviour long considered puzzling by astrophysicists.
Luke Benavitz, a graduate student at the University of Hawaiʻi Institute for Astronomy, collaborating with IfA astronomer Jeffrey Reep, has developed new models showing that time-dependent changes in elemental abundances — especially iron — can trigger fast cooling and condensation, creating plasma “rain” that descends through magnetic loops above the solar surface. Their study appears in The Astrophysical Journal.
Traditional solar flare and coronal models assume that the distribution of chemical elements in the corona remains fixed in both space and time. Those models struggle to reproduce how plasma condensations can form within minutes of a flare’s peak. Benavitz’s simulations incorporate a dynamic abundance field for low first ionisation potential elements like iron, silicon, and magnesium. Under this framework, material enriched in these elements accumulates near the apex of a magnetic loop, enhancing radiative losses locally and inducing runaway cooling. The result: rapid density growth and condensation into blobs that “rain” downward along the magnetic field lines.
Allowing for elemental flows means that portions of the corona may transiently become richer in low-FIP species. The redistribution amplifies local cooling and brings theory in line with observations of coronal rain forming during flares — a correspondence that fixed-abundance models could not achieve. Observationally, plasma blobs are seen streaming along post-flare magnetic loops, consistent with the new model’s outputs.
This revised approach may have far-reaching consequences for solar theory. Because cooling times depend on local composition, past estimates of flare dynamics may need re-evaluation. Cooling and condensation have often served as proxies for underlying heating — a link now rendered more complex by compositional feedback. Reep notes that if cooling time scales were systematically overestimated by prior models, then reconstructions of flare heating and energy transport need rethinking.
Independent observational studies lend weight to the new modelling. Spectroscopic analyses of loops after strong X-class flares have revealed bifurcations between photospheric and coronal composition signatures, with non-thermal velocities and density structures evolving as temperatures drop from millions to hundreds of thousands of kelvin. These signatures align with behaviour expected in compositional gradients driving condensation.
Magnetohydrodynamic simulations of eruptive flares further support the view that coronal rain emerges from catastrophic cooling in loop tops post-eruption, producing downward-falling condensations that agree in scale and speed with observed events. These models incorporate radiative losses, thermal conduction, and background heating to generate realistic plasma blob dynamics.
One open question is how the compositional gradients emerge and evolve. The new model treats elemental flows as a transported field but does not self-consistently generate FIP effects. Future refinements must integrate wave processes or ponderomotive forces that separate ions and neutrals in the chromosphere and feed composition drift into the corona.