Abstract:
Solar coronal jets are frequently occurring collimated ejections of solar plasma,
originating from magnetically mixed polarity locations on the Sun of size
scale comparable to that of a supergranule. Many, if not most, coronal jets
are produced by eruptions of small-scale filaments, or minifilaments, whose
magnetic field reconnects both with itself and also with surrounding coronal
field. There is evidence that minifilament eruptions are a scaled-down version
of typical filament eruptions that produce solar flares and coronal mass
ejections (CMEs). Moreover, the magnetic processes building up to and triggering
minifilament eruptions, which is often flux cancelation, might similarly build
up and trigger the larger filaments to erupt. Thus, detailed study of coronal
jets will inform us of the physics leading to, triggering, and driving the larger
eruptions. Additionally, such studies potentially can inform us of smaller-scale
coronal-jet-like features, such as jetlets and perhaps some spicules, that might
work the same way as coronal jets. We propose a high-resolution (∼0
′′
. 1 pixels),
high-cadence (∼5 s) EUV-solar-imaging mission for the upcoming decades, that
would be dedicated to observations of features of the coronal-jet size scale, and
smaller-scale solar features produced by similar physics. Such a mission could
provide invaluable insight into the operation of larger features such as CMEs
that produce significant Space Weather disturbances, and also smaller-scale
features that could be important for coronal heating, solar wind acceleration,
and heliospheric features such as the magnetic switchbacks that are frequently
observed in the solar wind.