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Main Authors: Warren, Donald C., Beauchemin, Catherine A. A., Barkov, Maxim V., Nagataki, Shigehiro
Format: Preprint
Published: 2020
Subjects:
Online Access:https://arxiv.org/abs/2010.06234
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author Warren, Donald C.
Beauchemin, Catherine A. A.
Barkov, Maxim V.
Nagataki, Shigehiro
author_facet Warren, Donald C.
Beauchemin, Catherine A. A.
Barkov, Maxim V.
Nagataki, Shigehiro
contents Relativistic shocks propagating into a medium with low magnetization are generated and sustained by small-scale but very strong magnetic field turbulence. This so-called "microturbulence" modifies the typical shock acceleration process, and in particular that of electrons. In this work we perform Monte Carlo (MC) simulations of electrons encountering shocks with microturbulent fields. The simulations cover a three-dimensional parameter space in shock speed, acceleration efficiency, and peak magnetic field strength. From these, a Markov Chain Monte Carlo (MCMC) method was employed to estimate the maximum electron momentum from the MC-simulated electron spectra. Having estimated this quantity at many points well-distributed over an astrophysically relevant parameter space, an MCMC method was again used to estimate the parameters of an empirical formula that computes the maximum momentum of a Fermi-accelerated electron population anywhere in this parameter space. The maximum energy is well-approximated as a broken power-law in shock speed, with the break occurring when the shock decelerates to the point where electrons can begin to escape upstream from the shock.
format Preprint
id arxiv_https___arxiv_org_abs_2010_06234
institution arXiv
publishDate 2020
record_format arxiv
spellingShingle The maximum energy of shock-accelerated electrons in a microturbulent magnetic field
Warren, Donald C.
Beauchemin, Catherine A. A.
Barkov, Maxim V.
Nagataki, Shigehiro
High Energy Astrophysical Phenomena
Relativistic shocks propagating into a medium with low magnetization are generated and sustained by small-scale but very strong magnetic field turbulence. This so-called "microturbulence" modifies the typical shock acceleration process, and in particular that of electrons. In this work we perform Monte Carlo (MC) simulations of electrons encountering shocks with microturbulent fields. The simulations cover a three-dimensional parameter space in shock speed, acceleration efficiency, and peak magnetic field strength. From these, a Markov Chain Monte Carlo (MCMC) method was employed to estimate the maximum electron momentum from the MC-simulated electron spectra. Having estimated this quantity at many points well-distributed over an astrophysically relevant parameter space, an MCMC method was again used to estimate the parameters of an empirical formula that computes the maximum momentum of a Fermi-accelerated electron population anywhere in this parameter space. The maximum energy is well-approximated as a broken power-law in shock speed, with the break occurring when the shock decelerates to the point where electrons can begin to escape upstream from the shock.
title The maximum energy of shock-accelerated electrons in a microturbulent magnetic field
topic High Energy Astrophysical Phenomena
url https://arxiv.org/abs/2010.06234