Stochastic Electron Acceleration by Temperature Anisotropy Instabilities Under Solar Flare Plasma Conditions

Abstract

Using 2D particle-in-cell (PIC) plasma simulations we study electron acceleration by temperature anisotropy instabilities, assuming conditions typical of above-the-loop-top (ALT) sources in solar flares. We focus on the long-term effect of Te, > Te, instabilities by driving the anisotropy growth during the entire simulation time, through imposing a shearing or a compressing plasma velocity (Te, and Te, are the temperatures perpendicular and parallel to the magnetic field). This magnetic growth makes Te,/Te, grow due to electron magnetic moment conservation, and amplifies the ratio ωce/ωpe from 0.53 to 2 (ωce and ωpe are the electron cyclotron and plasma frequencies, respectively). In the regime ωce/ωpe 1.2-1.7 the instability is dominated by oblique, quasi-electrostatic (OQES) modes, and the acceleration is inefficient. When ωce/ωpe has grown to ωce/ωpe 1.2-1.7, electrons are efficiently accelerated by the inelastic scattering provided by unstable parallel, electromagnetic z (PEMZ) modes. After ωce/ωpe reaches 2, the electron energy spectra show nonthermal tails that differ between the shearing and compressing cases. In the shearing case, the tail resembles a power-law of index αs 2.9 plus a high-energy bump reaching 300 keV. In the compressing runs, αs 3.7 with a spectral break above 500 keV. This difference can be explained by the different temperature evolutions in these two types of simulations, suggesting a critical role played by the type of anisotropy driving, ωce/ωpe and the electron temperature in the efficiency of the acceleration.