Abstract

Context. Despite the fact that electrons observed in situ in space plasmas have three major components - the quasi-thermal core, suprathermal halo, and strahl - the analysis of instabilities triggered by kinetic, velocity-space anisotropies (such as relative drifts and temperature anisotropy) generally considers only two of these components. Aims. We aim to demonstrate that a realistic modeling with all three components is achievable in the present analysis focusing on heat-flux instabilities. In the absence of particle-particle collisions, these instabilities are responsible for the regulation of the heat flux carried mainly by suprathermal electrons. Methods. The velocity distributions of the electron populations were modeled according to in situ observations, with a Maxwellian core and Kappa-distributed halo and strahl components. We exploited new advanced numerical codes capable of solving the linear dispersion and stability properties of any plasma system with Maxwellian- and Kappa-distributed populations. Results. The unstable solutions differ significantly from those obtained with simplified models with only two components (such as core-strahl or core-beam models). The growth rates predict the systematic excitation and interplay of two unstable modes, whistler heat-flux and/or fire-hose heat-flux instabilities. The numerical solver "ALPS" was successfully applied to systems with regularized Kappa distributions, for which the analytical derivation of dispersion relations is not straightforward.