Abstract
The Kelvin–Helmholtz (KH) instability of magnetohydrodynamic surface waves at the low latitude boundary layer is examined using both an eigenfrequency analysis and a time-dependent wave simulation. The analysis includes the effects of sheared flow and Alfvén velocity gradient. When the magnetosheath flows are perpendicular to the ambient magnetic field direction, unstable KH waves that propagate obliquely to the sheared flow direction occur at the sheared flow surface when the Alfvén Mach number is higher than an instability threshold. Including a shear transition layer between the magnetosphere and magnetosheath leads to secondary KH waves (driven by the sheared flow) that are coupled to the resonant surface Alfvén wave. There are remarkable differences between the primary and the secondary KH waves, including wave frequency, the growth rate, and the ratio between the transverse and compressional components. The secondary KH wave energy is concentrated near the shear Alfvén wave frequency at the magnetosheath with a lower frequency than the primary KH waves. Although the growth rate of the secondary KH waves is lower than the primary KH waves, the threshold condition is lower, so it is expected that these types of waves will dominate at a lower Mach number. Because the transverse component of the secondary KH waves is stronger than that of the primary KH waves, more efficient wave energy transfer from the boundary layer to the inner magnetosphere is also predicted.
Highlights
The Kelvin–Helmholtz (KH) instability has been widely investigated in the Earth’s magnetosphere (Johnson et al, 2014)
This article investigates the coupling between KH and Alfvén waves when a shear transition layer exists between the magnetosheath and magnetosphere
Using the eigenfrequency analysis and time-dependent wave simulations, we showed that the SKHWs are generated when the shear velocity is slower than the typical threshold value for the onset of the KH instability
Summary
The Kelvin–Helmholtz (KH) instability has been widely investigated in the Earth’s magnetosphere (Johnson et al, 2014). The RFI includes a negative absorption of the magnetosonic waves, and it has been investigated for the solar corona (Tirry et al, 1998; Andries et al, 2000; Andries and Goossens, 2001; Taroyan and Ruderman, 2011; Antolin and Van Doorsselaere, 2019), magnetopause (Ruderman and Wright, 1998; Taroyan and Erdélyi, 2002, 2003), and magnetotail (Turkakin et al, 2014), respectively While these works focused on shear in the velocity along the magnetic field direction, a similar instability can result in velocity shear across the magnetic field or for discontinuous changes in the magnetic field direction at velocity interfaces.
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