Pitch-Angle Anisotropy Imprinted by Relativistic Magnetic Reconnection

TL;DR

This study uses kinetic simulations to show that relativistic magnetic reconnection creates energy-dependent pitch-angle anisotropy in particles, influencing various astrophysical emission properties.

Contribution

It reveals how reconnection-driven particle acceleration imprints a broken power-law in energy and pitch-angle distributions, depending on magnetic field and magnetization parameters.

Findings

Reconnection produces broken power-law energy spectra and pitch-angle anisotropy.

Pitch-angle distributions depend on guide field strength and magnetization.

Anisotropy affects synchrotron emission, polarization, and cooling processes.

Abstract

Radiation emitted by nonthermal particles accelerated during relativistic magnetic reconnection is critical for understanding the nonthermal emission in a variety of astrophysical systems, including blazar jets, black hole coronae, pulsars, and magnetars. By means of fully kinetic Particle-in-Cell (PIC) simulations, we demonstrate that reconnection-driven particle acceleration imprints an energy-dependent pitch-angle anisotropy and gives rise to broken power laws in both the particle energy spectrum and the pitch-angle anisotropy. The particle distributions depend on the relative strength of the non-reconnecting (guide field) versus the reconnecting component of the magnetic field ($B_g/B_0$) and the lepton magnetization ($\sigma_0$). Below the break Lorentz factor $\gamma_0$ (injection), the particle energy spectrum is ultra-hard ($p_< < 1$), while above $\gamma_0$, the spectral index $p_>$ is highly sensitive to $B_g/B_0$. Particles' velocities align with the magnetic field, reaching minimum pitch angles $\alpha$ at a Lorentz factor $\gamma_{\min \alpha}$ controlled by $B_g/B_0$ and $\sigma_0$. The energy-dependent pitch-angle anisotropy, evaluated through the mean of $\sin^2 \alpha$ of particles at a given energy, exhibits power-law ranges with negative ($m_<$) and positive ($m_>$) slopes below and above $\gamma_{\min \alpha}$, becoming steeper as $B_g/B_0$ increases. The generation of anisotropic pitch angle distributions has important astrophysical implications. We address their effects on regulating synchrotron luminosity, spectral energy distribution, polarization, particle cooling, the synchrotron burnoff limit, emission beaming, and temperature anisotropy.