TY - CONF
T1 - Coronal Condensation at Preferential Topological Locations: The Birth of Solar Prominences and Coronal Rain
AU - Liu, Wei
AU - Sun, Xudong
AU - Yu, Sijie
AU - Antolin, Patrick
AU - Titov, Viacheslav
AU - Downs, Cooper
AU - Berger, Thomas
PY - 2019/6/1
Y1 - 2019/6/1
N2 - The million-degree hot and tenuous solar coronal plasma, under certain
conditions, can enigmatically undergo a radiative cooling instability
and condense into material of 100 times cooler in the form of
prominences or coronal rain. Where, when, and how such cooling
condensation takes place remain poorly understood. Answers to these
questions are not only of scientific importance in their own right, but
also bear implications for the fundamental question of coronal heating
and the chromosphere-corona mass cycle. Magnetic fields in the
magnetized corona undoubtedly play a crucial role (e.g., by trapping the
plasma), but where and how? We report recent imaging and spectroscopic
observations from SDO/AIA/HMI and IRIS that can shed light on these
puzzles. Through a systematic survey, we found that a large fraction of
quiet-Sun condensations preferentially occur at the dips of coronal
loops or funnels. Such dips are located at/near magnetic topological
features, such as null points and quasi-separatrix layers (QSLs), which
are regions characterized by high values of the squashing factor. We
also identified evidence of magnetic reconnection at such locations,
which can produce favorable conditions, e.g., density enhancement by
compression and/or mass trapping in plasmoids, that can trigger run-away
radiative cooling. We will discuss the significance and broader
implications of these novel observations.
AB - The million-degree hot and tenuous solar coronal plasma, under certain
conditions, can enigmatically undergo a radiative cooling instability
and condense into material of 100 times cooler in the form of
prominences or coronal rain. Where, when, and how such cooling
condensation takes place remain poorly understood. Answers to these
questions are not only of scientific importance in their own right, but
also bear implications for the fundamental question of coronal heating
and the chromosphere-corona mass cycle. Magnetic fields in the
magnetized corona undoubtedly play a crucial role (e.g., by trapping the
plasma), but where and how? We report recent imaging and spectroscopic
observations from SDO/AIA/HMI and IRIS that can shed light on these
puzzles. Through a systematic survey, we found that a large fraction of
quiet-Sun condensations preferentially occur at the dips of coronal
loops or funnels. Such dips are located at/near magnetic topological
features, such as null points and quasi-separatrix layers (QSLs), which
are regions characterized by high values of the squashing factor. We
also identified evidence of magnetic reconnection at such locations,
which can produce favorable conditions, e.g., density enhancement by
compression and/or mass trapping in plasmoids, that can trigger run-away
radiative cooling. We will discuss the significance and broader
implications of these novel observations.
M3 - Abstract
ER -