Saved in:
Bibliographic Details
Main Author: Kang, Hyesung
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2409.18425
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866916412507815936
author Kang, Hyesung
author_facet Kang, Hyesung
contents During the formation of large-scale structures in the universe, weak internal shocks are induced within the hot ICM, while strong accretion shocks arise in the WHIM within filaments, and the warm-cold gas in voids surrounding galaxy clusters. These cosmological shocks are thought to accelerate cosmic ray (CR) protons and electrons via diffusive shock acceleration. Recent advances in particle-in-cell and hybrid simulations have provided deeper insights into the kinetic plasma processes that govern microinstabilities and particle acceleration in collisionless shocks in weakly magnetized astrophysical plasma. In this study, we adopt a thermal-leakage type injection model and DSA power-law distribution functions in the test-particle regime. The CR proton spectrum directly connects to the Maxwellian distribution of protons at the injection momentum $p_{\rm{inj}} = Q_p p_{\rm {th,p}}$. On the other hand, the CR electron spectrum extends down to $p_{\rm{min}}=Q_ep_{\rm{th,e}}$ and is linked to the Maxwellian distribution of electrons. Here, $p_{\rm{th,p}}$ and $p_{\rm{th,e}}$, are the proton and electron thermal momenta, respectively. Moreover, we propose that the postshock gas temperature and the injection parameters, $Q_p$ and $Q_e$ are self-regulated to maintain the test-particle condition, as the thermal energy is gradually transferred to the CR energy. Under these constraints, we estimate the self-regulated values of the temperature reduction factor, $R_T$, and the proton injection parameter, $Q_p$, along with the resulting CR efficiencies, $η_p$ and $η_e$. We then provide analytical fitting functions for these parameters as functions of the shock Mach number, $M_s$. These fitting formulas may serve as valuable tools for quantitatively assessing the impact of CR protons and electrons, as well as the resulting nonthermal emissions in galaxy clusters and cosmic filaments.
format Preprint
id arxiv_https___arxiv_org_abs_2409_18425
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Diffusive Shock Acceleration Efficiencies for Weak ICM Shocks in the Test Particle Regime
Kang, Hyesung
High Energy Astrophysical Phenomena
During the formation of large-scale structures in the universe, weak internal shocks are induced within the hot ICM, while strong accretion shocks arise in the WHIM within filaments, and the warm-cold gas in voids surrounding galaxy clusters. These cosmological shocks are thought to accelerate cosmic ray (CR) protons and electrons via diffusive shock acceleration. Recent advances in particle-in-cell and hybrid simulations have provided deeper insights into the kinetic plasma processes that govern microinstabilities and particle acceleration in collisionless shocks in weakly magnetized astrophysical plasma. In this study, we adopt a thermal-leakage type injection model and DSA power-law distribution functions in the test-particle regime. The CR proton spectrum directly connects to the Maxwellian distribution of protons at the injection momentum $p_{\rm{inj}} = Q_p p_{\rm {th,p}}$. On the other hand, the CR electron spectrum extends down to $p_{\rm{min}}=Q_ep_{\rm{th,e}}$ and is linked to the Maxwellian distribution of electrons. Here, $p_{\rm{th,p}}$ and $p_{\rm{th,e}}$, are the proton and electron thermal momenta, respectively. Moreover, we propose that the postshock gas temperature and the injection parameters, $Q_p$ and $Q_e$ are self-regulated to maintain the test-particle condition, as the thermal energy is gradually transferred to the CR energy. Under these constraints, we estimate the self-regulated values of the temperature reduction factor, $R_T$, and the proton injection parameter, $Q_p$, along with the resulting CR efficiencies, $η_p$ and $η_e$. We then provide analytical fitting functions for these parameters as functions of the shock Mach number, $M_s$. These fitting formulas may serve as valuable tools for quantitatively assessing the impact of CR protons and electrons, as well as the resulting nonthermal emissions in galaxy clusters and cosmic filaments.
title Diffusive Shock Acceleration Efficiencies for Weak ICM Shocks in the Test Particle Regime
topic High Energy Astrophysical Phenomena
url https://arxiv.org/abs/2409.18425