Authors: Hanqing Ma (University of Maryland), J. F. Drake (University of Maryland), M. Swisdak (University of Maryland)
The consequences of a 90◦ barrier in the scattering of energetic electrons by whistler waves is explored with self-consistent two-dimensional particle-in-cell simulations. In the presence of a 90◦ scattering barrier a field-aligned heat flux of energetic electrons will rapidly scatter to form a uniform distribution with pitch angles 0 < θ < 90◦ but with a discontinuous jump at θ = 90◦ to a lower energy distribution of electrons with 90◦ < θ < 180◦. However, simulations reveal that such a distribution contains a large reservoir of free energy that is released to drive large-amplitude, oblique-propagating whistler waves (δB/B0 ∼ 0.1). As a result, energetic electrons near pitch angle 90◦ experience strong resonance scattering. Nearly half of the energetic electrons in the positive parallel velocity plane cross the 90◦ barrier and diffuse to negative parallel velocities. Thus, the late-time electron velocity distribution becomes nearly isotropic. This result has implications for understanding the regulation of energetic particle heat flux in space and astrophysical environments, including the solar corona, the solar wind and the intracluster medium of galaxy clusters.