Pair Plasma in Super-QED Magnetic Fields and the Hard X-ray/Optical Emission of Magnetars

TL;DR

This paper models the photon spectrum emitted by pair plasmas in ultrastrong magnetic fields of magnetars, explaining their hard X-ray/optical emissions through quantum electrodynamics processes and stable magnetospheric configurations.

Contribution

It introduces a novel model of magnetar magnetospheres with high plasma density and pair creation, linking quantum electrodynamics calculations to observed emissions.

Findings

Reproduces the rising hard X-ray spectra of quiescent magnetars.

Identifies magnetospheric arcades as sites of persistent X-ray emission.

Explains optical-IR emission via annihilation bremsstrahlung.

Abstract

The photon spectrum emitted by a transrelativistic pair plasma is calculated in the presence of an ultrastrong magnetic field, and is shown to bear a remarkable resemblance to the rising hard X-ray spectra of quiescent magnetars. This emission is powered by pair annihilation which, in contrast with a weakly magnetized pair plasma, shows an extended low-frequency tail similar to bremsstrahlung. Cross sections for electron-positron annihilation/scattering, two-photon pair creation, and photon-$e^\pm$ scattering are adopted from our earlier ab initio QED calculations in the regime $10\alpha_{\rm em}^{-1}B_{\rm Q} \gg B \gg B_{\rm Q}$. Careful attention is given to the $u$-channel scattering resonance. Magnetospheric arcades anchored in zones of intense crustal shear and extending to about twice the magnetar radius are identified as the sites of the persistent hard X-ray emission. We deduce a novel and stable configuration for the magnetospheric circuit, with a high plasma density sustained by ohmic heating and in situ pair creation. Pairs are sourced non-locally by photon collisions in zones with weak currents, such as the polar cap. Annihilation bremsstrahlung extends to the optical-IR band, where the plasma cutoff is located. The upper magnetar atmosphere experiences strong current-driven growth of ion-acoustic turbulence, which may limit positron diffusion. Coherent optical-IR emission is bounded near the observed flux by induced scattering. This model accommodates the rapid X-ray brightening of an activating magnetar, concentrated thermal hotspots, and the subdominant thermal X-ray emission of some active magnetars. Current injection is ascribed to continuous magnetic braiding, as seen in the global yielding calculations of Thompson, Yang & Ortiz.