Abstract
Arch-like loop structures filled with million Kelvin hot plasma form the building blocks of the quiet-Sun corona. Both high-resolution observations and magnetoconvection simulations show the ubiquitous presence of magnetic fields on the solar surface on small spatial scales of ∼100 km. However, the question of how exactly these quiet-Sun coronal loops originate from the photosphere and how the magnetic energy from the surface is channeled to heat the overlying atmosphere is a long-standing puzzle. Here we report high-resolution photospheric magnetic field and coronal data acquired during the second science perihelion of Solar Orbiter that reveal a highly dynamic magnetic landscape underlying the observed quiet-Sun corona. We found that coronal loops often connect to surface regions that harbor fleeting weaker, mixed-polarity magnetic field patches structured on small spatial scales, and that coronal disturbances could emerge from these areas. We suggest that weaker magnetic fields with fluxes as low as 1015 Mx and/or those that evolve on timescales less than 5 minutes are crucial to understanding the coronal structuring and dynamics.
Original language | English |
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Article number | L1 |
Number of pages | 10 |
Journal | apjl |
Volume | 956 |
Issue number | 1 |
DOIs | |
Publication status | Published - 1 Oct 2023 |
Keywords
- Solar extreme ultraviolet emission
- Solar photosphere
- Solar coronal heating
- Solar magnetic fields
- Solar magnetic reconnection
- Magnetohydrodynamics
- Solar coronal loops
- Astrophysics - solar and stellar astrophysics
- Physics - plasma physics
- Physics - space physics