In-situ Measurement of the Energy Fraction in Supra-thermal and Energetic Particles at ACE, Wind, and PSP Interplanetary Shocks

Abstract

The acceleration of charged particles by interplanetary shocks (IPs) can drain a non-negligible fraction of the plasma pressure. In this study, we have selected 17 IPs observed in-situ at 1\,au by the Advanced Composition Explorer (ACE) and the Wind spacecraft, and 1 shock at 0.8\,au observed by Parker Solar Probe (PSP). We have calculated the time-dependent partial pressure of supra-thermal and energetic particles (smaller and greater than 50\,keV for protons and 30\,keV for electrons, respectively) in both the upstream and downstream regions. The particle fluxes were averaged for 1 hour before and 1 hour after the shock time to remove short time scale effects. Using the MHD Rankine-Hugoniot jump conditions, we find that the fraction of the total upstream energy flux transferred to supra-thermal and energetic downstream particles is typically \!16\%, in agreement with previous observations and simulations. Notably, by accounting for errors on all measured shock parameters, we have found that for any given fast magnetosonic Mach number, Mf\!<7, the angle between the shock normal and average upstream magnetic field, θBn, is not correlated with the energetic particle pressure; in particular, the partial pressure of energized particles does not decrease for θBn 45. The downstream electron-to-proton energy ratio in the range \!140\,eV for electrons and \!70\,keV for protons exceeds the expected \!1\% and nears equipartition (>\!0.1) for the Wind events.