Radio Emission of Pulsars. I. Slow Tearing of a Quantizing Magnetic Field

TL;DR

This paper investigates the stability of magnetic fields in pulsars, identifying slow tearing modes driven by resistive instabilities that could explain pulsar radio emission variability.

Contribution

It introduces a detailed analysis of relativistic tearing modes in quantizing magnetic fields within pulsars, linking these modes to observed radio emission phenomena.

Findings

Multiple tearing mode branches with growth rates comparable to pulsar rotation frequency.

Localized tearing modes in thin current sheets with growth rate scaling as (thickness/skin depth)^-1/2.

Resistive modes potentially driving pulse-to-pulse flux variations in pulsars.

Abstract

The pulsed radio emission of rotating neutron stars is connected to slow resistive instabilities feeding off an inhomogeneous twist profile within the open circuit. This paper considers the stability of a weakly sheared, quantizing magnetic field in which the current is supported by a relativistic particle flow. The electromagnetic field is almost perfectly force-free, and the particles are confined to the lowest Landau state, experiencing no appreciable curvature drift. In a charge-neutral plasma, we find multiple branches of slowly growing tearing modes, relativistic analogs of the double tearing mode, with peak growth rate $s \gtrsim 4\pi \widetilde k_y J_z/B_z$. Here, $B_z$ is the strong (nearly potential) guide magnetic field, $J_z$ the field-aligned current density, and $\widetilde k_y$ is the mode wavenumber normalized by the current gradient scale. These modes are overstable when the plasma carries net charge, with real frequency $\omega \sim s\cdot |n_0^+ - n_0^-|/(n_0^+ + n_0^-)$ proportional to the imbalance in the densities of positive and negative charges. An isolated current sheet thinner than the skin depth supports localized tearing modes with growth rate scaling as (sheet thickness/skin depth)$^{-1/2}$. In a pulsar, the peak growth rate is comparable to the angular frequency of rotation, $s \gtrsim 2\widetilde k_y \Omega$, slow compared with the longitudinal oscillations of particles and fields in a polar gap. The resistive modes experience azimuthal drift reminiscent of sub-pulse drift and are a promising driver of pulse-to-pulse flux variations. A companion paper demonstrates a Cerenkov-like instability of current-carrying Alfv\'en waves in thin current sheets with relativistic particle flow, and proposes coherent curvature emission by these waves as a source of pulsar radio emission.