Abstract
Context. Magnetic null points are associated with high-energy coronal phenomena such as solar flares and are often sites of reconnection and particle acceleration. Dynamic twisting of a magnetic null point can generate a Kelvin-Helmholtz instability (KHI) within its fan plane and can instigate spine-fan reconnection and an associated collapse of the null point under continued twisting. Aims. This article aims to compare the effects of isotropic and anisotropic viscosity in simulations of the KHI and collapse in a dynamically twisted magnetic null point. Methods. We performed simulations using the 3D magnetohydrodynamics code Lare3d with a custom anisotropic viscosity module. A pair of high-resolution simulations were performed, one using isotropic viscosity and another using anisotropic viscosity, keeping all other factors identical. We analysed the results in detail. A further parameter study was performed over a range of values for viscosity and resistivity. Results. Both viscosity models permit the growth of the KHI and the eventual collapse of the null point. Over all studied parameters, anisotropic viscosity allows a faster growing instability, while isotropic viscosity damps the instability to the extent of stabilisation in some cases. Although the viscous heating associated with anisotropic viscosity is generally smaller, the ohmic heating dominates and is enhanced by the current sheets generated by the instability. This leads to a greater overall heating rate when using anisotropic viscosity. The collapse of the null point occurs significantly sooner when anisotropic viscosity is employed.
Highlights
This paper presents the results of a series of numerical experiments intended to develop an understanding of the effect of anisotropic viscosity on the Kelvin-Helmholtz instability (KHI) in the fan plane of a magnetic null point, reproducing and extending the work of Wyper & Pontin (2013)
The experiments take the form of a dynamic twisting of an initially static magnetic null point at the footpoints of its spine, resulting in a current-vortex sheet that forms in the fan plane and can be unstable to the KHI, given appropriate parameter choices
Stability measures Following Wyper & Pontin (2013), two quantities are used to understand the stability of the current-vortex sheet: the fast mode Mach number Mf, associated with the velocity shear, and a parameter Λ describing the balance of stability between the tearing mode and the KHI in a current-vortex sheet1
Summary
This paper presents the results of a series of numerical experiments intended to develop an understanding of the effect of anisotropic viscosity on the Kelvin-Helmholtz instability (KHI) in the fan plane of a magnetic null point, reproducing and extending the work of Wyper & Pontin (2013). We continue to stress the null point beyond the time investigated in Wyper & Pontin (2013), which allows us to study the effect of anisotropic viscosity on the spontaneous collapse of the null point. The experiments take the form of a dynamic twisting of an initially static magnetic null point at the footpoints of its spine, resulting in a current-vortex sheet that forms in the fan plane and can be unstable to the KHI, given appropriate parameter choices. Continued driving after the moment at which the KHI occurs causes the null point to spontaneously undergo spine-fan reconnection and collapse
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