Pulsar timing irregularities and the imprint of magnetic field evolution

TL;DR

This paper explores how magnetic field evolution in neutron stars affects their rotational braking index, revealing three evolutionary stages with distinct observational signatures through advanced simulations.

Contribution

It introduces detailed magneto-thermal evolution models showing how magnetic field changes influence pulsar timing properties over different stellar ages.

Findings

Braking index varies with star age and temperature, showing three distinct stages.

Strong multipolar or toroidal fields can explain observed timing behaviors.

Hall oscillations cause high-amplitude variations in braking index at late times.

Abstract

(Abridged) The rotational evolution of isolated neutron stars is dominated by the magnetic field anchored to the solid crust of the star. Assuming that the core field evolves on much longer timescales, the crustal field evolves mainly though Ohmic dissipation and the Hall drift, and it may be subject to relatively rapid changes with remarkable effects on the observed timing properties. We investigate whether changes of the magnetic field structure and strength during the star evolution may have observable consequences in the braking index, which is the most sensitive quantity to reflect small variations of the timing properties that are caused by magnetic field rearrangements. By performing axisymmetric, long-term simulations of the magneto-thermal evolution of neutron stars with state-of-the-art microphysical inputs, we find that the effect of the magnetic field evolution on the braking index can be divided into three qualitatively different stages depending on the age and the internal temperature: a first stage that may be different for standard pulsars (with n~3) or low field neutron stars that accreted fallback matter during the supernova explosion (systematically n<3); in a second stage, the evolution is governed by almost pure Ohmic field decay, and a braking index n>3 is expected; in the third stage, at late times, when the interior temperature has dropped to very low values, Hall oscillatory modes in the neutron star crust result in braking indices of high absolute value and both positive and negative signs. Models with strong (1e14 G) multipolar or toroidal components, even with a weak (~1e12 G) dipolar field are consistent with the observed trend of the timing properties.