Refinement of the timing-based estimator of pulsar magnetic fields

Abstract

Numerical simulations of realistic non-vacuum magnetospheres of isolated neutron stars have shown that pulsar spin-down luminosities depend weakly on the magnetic obliquity. This result provides the opportunity to estimate the surface magnetic field for a given radiopulsar with quite a high accuracy. In the current work, we present a refinement of the classical `magneto-dipolar' formula for pulsar magnetic fields B md = (3.2× 1019 G)P P, where P is the neutron star spin period. The new, robust timing-based estimator is introduced as B = B md + B(M, α), where the correction B depends on the equation of state (EOS) of dense matter, the individual pulsar obliquity α and the mass M. Adopting state-of-the-art statistics for M and α we calculate the distributions of B for a representative subset of 22 EOSs that do not contradict observations. It has been found that B is distributed nearly normally, with the average in the range -0.5 to -0.25 dex and standard deviation σ[ B] ≈ 0.06 to 0.09 dex, depending on the adopted EOS. The latter quantity represents a formal uncertainty of the corrected estimation of B because B is weakly correlated with B md. At the same time, if it is assumed that every considered EOS has the same chance of occurring in nature, then another, more generalized, estimator B* ≈ 3B md/7 can be introduced providing an unbiased value of the pulsar surface magnetic field with 30 per cent uncertainty with 68 per cent confidence. Finally, we discuss the possible impact of pulsar timing irregularities on the timing-based estimation of B and review the astrophysical applications of the obtained results.