Abstract
Recent observations support the propagation of a number of magnetohydrodynamic (MHD) modes which, under some conditions, can become unstable and the developing instability is the Kelvin--Helmholtz instability (KHI). In its nonlinear stage the KHI can trigger the occurrence of wave turbulence which is considered as a candidate mechanism for coronal heating. We review the modeling of tornado-like phenomena in the solar chromosphere and corona as moving weakly twisted and spinning cylindrical flux tubes, showing that the KHI rises at the excitation of high-mode MHD waves. The instability occurs within a wavenumber range whose width depends on the MHD mode number \emph{m}, the plasma density contrast between the rotating jet and its environment, and also on the twists of the internal magnetic field and the jet velocity. We have studied KHI in two twisted spinning solar polar coronal hole jets, in a twisted rotating jet emerging from a filament eruption, and in a rotating macrospicule. The theoretically calculated KHI development times of a few minutes for wavelengths comparable to the half-widths of the jets are in good agreement with the observationally determined growth times only for high order (10 $\mathrm{\leqslant}$ \emph{m} $\mathrm{\leqslant}$ 65) MHD modes. Therefore, we expect that the observed KHI in these cases is due to unstable high-order MHD modes.
Highlights
Solar jets are ubiquitous in the solar atmosphere and recent observations have revealed that they are related to small scale filament eruptions
The targets of our exploration are: (i) the spinning coronal hole jet of 2010 August 21 (Chen et al, 2012); (ii) the rotating coronal hole jet of 2011 February 8 (Young and Muglach, 2014a), (iii) the twisted rotating jet emerging from a filament eruption on 2013 April 10–11 (Filippov et al, 2015), and (iv) the rotating macrospicule observed by Pike and Mason (1998) on 1997 March 8
We have studied the emerging of Kelvin–Helmholtz instability (KHI) in four different spinning solar jets due to the excitation of high-mode (m 2) MHD waves traveling along the jets
Summary
Solar jets are ubiquitous in the solar atmosphere and recent observations have revealed that they are related to small scale filament eruptions. The authors used the standard procedure for exploring the MHD wave propagation in cylindrical flows considering that all the perturbations of the plasma pressure p, fluid velocity v, and magnetic field B, are ∝ exp[i(−ωt + kz + mθ )]. The found solutions in both media (the jet and its environment) are merged at the perturbed tube boundary through the conditions for continuity of the total (thermal plus magnetic) pressure and the Lagrangian displacement The latter is defined as the ratio of radial velocity perturbation component and the angular frequency in the corresponding medium. The main goal of this review article is to suggest a way of using the wave dispersion relation derived in Zaqarashvili et al (2015) to study the possibility for the rising and development of KHI in rotating twisted solar jets.
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