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Main Authors: Yan, Kai, Yan, Huirong, Pavaskar, Parth, Hou, Chuanpeng, Liu, Ruo-Yu
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.19037
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author Yan, Kai
Yan, Huirong
Pavaskar, Parth
Hou, Chuanpeng
Liu, Ruo-Yu
author_facet Yan, Kai
Yan, Huirong
Pavaskar, Parth
Hou, Chuanpeng
Liu, Ruo-Yu
contents Cosmic-ray pitch-angle transport in magnetohydrodynamic (MHD) turbulence is governed by the interplay between magnetic mirroring and gyroresonant scattering. We develop a guiding-center (GC) Langevin model with explicit mirror drift and gyroresonant diffusion to describe the pitch angle evolution. This model accurately captures our test-particle simulation results in three-dimensional MHD turbulence, driven both solenoidally and compressively. We find that magnetic mirroring can drive anomalous pitch-angle diffusion at large pitch angles (including $90^\circ$) with non-Markovian memory effects, which arises from trapping of particles in magnetic wells. Gyroresonant scattering controls the escape rate from these wells. Across $M_{\rm A}$, large-pitch-angle particles are jointly regulated by mirror trapping and gyroresonant escape, exhibiting a transition from anomalous to normal diffusive pitch-angle transport as scattering strengthens, whereas small-pitch-angle particles remain gyroresonance-dominated and diffusive throughout. The pitch angle transport is found to be dominated by the compressible perturbations with marginal influence from Alfvén modes. In compressible turbulence with realistic damping accounted for, transit time damping (TTD) treatment fully recovers mirror interactions.
format Preprint
id arxiv_https___arxiv_org_abs_2603_19037
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Non-Markovian Cosmic-Ray Pitch-Angle Transport from Mirror Interactions
Yan, Kai
Yan, Huirong
Pavaskar, Parth
Hou, Chuanpeng
Liu, Ruo-Yu
High Energy Astrophysical Phenomena
Cosmic-ray pitch-angle transport in magnetohydrodynamic (MHD) turbulence is governed by the interplay between magnetic mirroring and gyroresonant scattering. We develop a guiding-center (GC) Langevin model with explicit mirror drift and gyroresonant diffusion to describe the pitch angle evolution. This model accurately captures our test-particle simulation results in three-dimensional MHD turbulence, driven both solenoidally and compressively. We find that magnetic mirroring can drive anomalous pitch-angle diffusion at large pitch angles (including $90^\circ$) with non-Markovian memory effects, which arises from trapping of particles in magnetic wells. Gyroresonant scattering controls the escape rate from these wells. Across $M_{\rm A}$, large-pitch-angle particles are jointly regulated by mirror trapping and gyroresonant escape, exhibiting a transition from anomalous to normal diffusive pitch-angle transport as scattering strengthens, whereas small-pitch-angle particles remain gyroresonance-dominated and diffusive throughout. The pitch angle transport is found to be dominated by the compressible perturbations with marginal influence from Alfvén modes. In compressible turbulence with realistic damping accounted for, transit time damping (TTD) treatment fully recovers mirror interactions.
title Non-Markovian Cosmic-Ray Pitch-Angle Transport from Mirror Interactions
topic High Energy Astrophysical Phenomena
url https://arxiv.org/abs/2603.19037