The distribution of tilt angles in newly born NSs: role of interior viscosity and magnetic field

TL;DR

This paper investigates how interior viscosity influences the tilt angle distribution in young neutron stars, proposing a bi-modal distribution model consistent with observations and predicting detectable gravitational waves.

Contribution

It introduces a model linking interior viscosity and magnetic field configurations to tilt angle distributions, challenging previous assumptions about neutron star shape determination.

Findings

Bi-modal tilt angle distribution explained by bulk viscosity dissipation.

Crab pulsar's ellipticity estimated at ^{-6}.

Predicted gravitational wave signals could be detected by Advanced LIGO/Virgo.

Abstract

We study how the viscosity of neutron star (NS) matter affects the distribution of tilt angles ($\chi$) between the spin and magnetic axes in young pulsars. Under the hypothesis that the NS shape is determined by the magnetically-induced deformation, and that the toroidal component of the internal magnetic field exceeds the poloidal one, we show that the dissipation of precessional motions by bulk viscosity can naturally produce a bi-modal distribution of tilt angles, as observed in radio/$\gamma$-ray pulsars, with a low probability of achieving $\chi \sim (20^\circ - 70^\circ)$ if the interior B-field is $\sim (10^{11} - 10^{15})$~G and the birth spin period is $\sim 10 - 300$~ms. As a corollary of the model, the idea that the NS shape is solely determined by the poloidal magnetic field, or by the centrifugal deformation of the crust, is found to be inconsistent with the tilt angle distribution in young pulsars. When applied to the Crab pulsar, with $\chi \sim 45^\circ - 70^\circ$ and birth spin $\sim$ 20 ms, our model implies that: (i) the magnetically-induced ellipticity is $\epsilon_B \gtrsim 3 \times 10^{-6}$; (ii) the measured positive $\dot{\chi} \sim 3.6 \times 10^{-12}$ rad s$^{-1}$ requires an additional viscous process, acting on a timescale $\lesssim 10^4$ yrs. We interpret the latter as crust-core coupling via mutual friction in the superfluid NS interior. One critical implication of our model is a GW signal at (twice) the spin frequency of the NS, due to $\epsilon_B \sim 10^{-6}$. This could be detectable by Advanced LIGO/Virgo operating at design sensitivity.