Evaluation of Kinetic Ballooning Instability in the Near-Earth Magnetotail

Abstract

Ballooning instabilities are widely believed to be a possible triggering mechanism for the onset of substorm and current disruption initiation in the near-Earth magnetotail. Yet the stability of the kinetic ballooning mode (KBM) in a global and realistic magnetotail configuration has not been well examined. In this paper, the growth rate of the KBM is calculated from analytical theory for the two-dimensional Voigt equilibrium within the framework of kinetic magnetohydrodynamic (MHD) model. The growth rate of the KBM is found to be strongly dependent on the field line stiffening factor S, which depends on the trapped electron dynamics, the finite ion gyroradius, and the magnetic drift motion of charged particles. Furthermore, calculations show that the KBM is unstable in a finite intermediate range of equatorial βeq values and the growth rate dependence on βeq is enhanced for larger i. The KBM stability is further analyzed in a broad range of ky for different values of ion Larmor radius i and gradient ratio ηj d(Tj)/d(nj), where Tj is the particle temperature and nj is the particle density. The KBM is found to be unstable for sufficiently high values of ky, where the growth rate first increases to a maximum value and then decreases due to kinetic effects. The ky at the maximum growth rate decreases exponentially with i. The current sheet thinning is found to enhance the KBM growth rate and the unstable βeq regime in the near-Earth magnetotail.