Magnetic energy dissipation and gamma-ray emission in energetic pulsars

TL;DR

This paper models energetic pulsar magnetospheres using 3D particle-in-cell simulations with synchrotron cooling to understand gamma-ray emission and energy dissipation mechanisms, linking microphysical processes to observed spectra.

Contribution

It introduces a detailed simulation framework that connects magnetic reconnection, particle acceleration, and spectral features in pulsar gamma-ray emission.

Findings

Magnetic reconnection rate depends on pulsar inclination angle.

Maximum particle energy is controlled by magnetic energy per particle.

Spectral shapes are influenced by synchrotron cooling strength.

Abstract

Some of the most energetic pulsars exhibit rotation-modulated gamma-ray emission in the $0.1$ to $100$ GeV band. The luminosity of this emission is typically $0.1\text{-}10\%$ of the pulsar spin-down power (gamma-ray efficiency), implying that a significant fraction of the available electromagnetic energy is dissipated in the magnetosphere and reradiated as high-energy photons. To investigate this phenomenon we model a pulsar magnetosphere using 3D particle-in-cell simulations with strong synchrotron cooling. We particularly focus on the dynamics of the equatorial current sheet where magnetic reconnection and energy dissipation take place. Our simulations demonstrate that a fraction of the spin-down power dissipated in the magnetospheric current sheet is controlled by the rate of magnetic reconnection at microphysical plasma scales and only depends on the pulsar inclination angle. We demonstrate that the maximum energy and the distribution function of accelerated pairs is controlled by the available magnetic energy per particle near the current sheet, the magnetization parameter. The shape and the extent of the plasma distribution is imprinted in the observed synchrotron emission, in particular, in the peak and the cutoff of the observed spectrum. We study how the strength of synchrotron cooling affects the observed variety of spectral shapes. Our conclusions naturally explain why pulsars with higher spin-down power have wider spectral shapes and, as a result, lower gamma-ray efficiency.