Measuring the crust-superfluid coupling time-scale for 105 UTMOST pulsars with a Kalman filter
Abstract
Crust-superfluid coupling plays an important role in neutron star rotation, particularly with respect to timing noise and glitches. Here, we present new timing-noise-based estimates of the crust-superfluid coupling time-scale \(τ\) for 105 radio pulsars in the UTMOST dataset, by Kalman filtering the pulse times of arrival. The 105 objects are selected because they favor a two-component, crust-superfluid model over a one-component model with log Bayes factor \( B BF ≥ 5\). The median estimate of \(τ\) ranges from \(104.60.4\)\,s for PSR J2241-5236 to \(107.7+0.7-0.4\)\,s for PSR J1644-4559 among 28 out of 105 objects with sharply peaked \(τ\) posteriors. A hierarchical Bayesian analysis is performed on 101 out of 105 objects that are canonical (i.e.\ neither recycled nor magnetars) and reside in the populous core of the \( c\)-\( c\) plane. It returns the population-level scaling \(τ c0.19+0.50-0.52 | c|0.18+0.18-0.19\), where \( c\) and \( c\) are the angular velocity and spin-down rate of the crust respectively. The variances of the stochastic crust and superfluid torques are also estimated hierarchically, with \(Q c c1.23+0.80-0.75 | c|0.49+0.27-0.32\) and \(Q s c0.71+0.76-0.78 | c|1.27+0.30-0.28\) respectively. Implications for the physical origin of crust-superfluid coupling, e.g.\ through mutual friction, are discussed briefly.
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