Abstract:
We perform a 2.5D magnetohydrodynamic simulation to gain a comprehensive understanding of the formation of spicule-like
cool jets caused by initial transverse velocity pulses akin to Alfven´ pulses in the solar chromosphere. We invoke multiple
velocity (Vz) pulses between 1.5 and 2.0 Mm in the solar atmosphere, which create the initial transverse velocity perturbations.
These pulses transfer energy non-linearly to the field-aligned perturbations via the ponderomotive force. This physical process
further creates magnetoacoustic shocks followed by quasi-periodic plasma motions in the solar atmosphere. The field-aligned
magnetoacoustic shocks move upwards, which subsequently causes the quasi-periodic rise and fall of chromospheric plasma
into the overlying corona as thin and cool spicule-like jets. The magnitude of the initial applied transverse velocity pulses is
taken in the range of 50–90 km s−1. These pulses are found to be strong enough to generate spicule-like jets. We analyse the
evolution, kinematics and energetics of these spicule-like jets. We find that the transported mass flux and kinetic energy density
are substantial in the local solar corona. These mass motions generate in situ quasi-periodic oscillations on the scale of 4.0 min
above the transition region.
