Repeating Fast Radio Bursts with High Burst Rates by Plate Collisions in Neutron Star Crusts

TL;DR

This paper proposes a model where plate collisions in neutron star crusts cause high-rate repeating fast radio bursts, explaining observed burst rates and energy distributions, and matching properties of FRB 121102.

Contribution

It introduces a novel mechanism linking crustal plate collisions in neutron stars to high burst rates in repeating FRBs, supported by quantitative predictions.

Findings

Predicted burst rate up to 770 h^{-1} for certain neutron star parameters.

Derived waiting time and energy distribution consistent with FRB 121102 observations.

Model explains high burst rates through crustal plate collisions in young neutron stars.

Abstract

Some repeating fast radio burst (FRB) sources show high burst rates, and the physical origin is still unknown. Outstandingly, the first repeater FRB 121102 appears extremely high burst rate with the maximum value reaching $122\,\mathrm{h^{-1}}$ or even higher. In this work, we propose that the high burst rate of an FRB repeater may be due to plate collisions in the crust of young neutron stars (NSs). In the crust of an NS, vortex lines are pinned to the lattice nuclei. When the relative angular velocity between the superfluid neutrons and the NS lattices is nonzero, a pinned force will act on the vortex lines, which will cause the lattice displacement and the strain on the NS crust growing. With the spin evolution, the crustal strain reaches a critical value, then the crust may crack into plates, and each of plates will collide with its adjacent ones. The Aflv\'en wave could be launched by the plate collisions and further produce FRBs. In this scenario, the predicted burst rate can reach $\sim 770\,\mathrm{h}^{-1}$ for an NS with the magnetic field of $10^{13}\,\rm{G}$ and the spin period of $0.01\,\rm{s}$. We further apply this model to FRB 121102, and predict the waiting time and energy distribution to be $P(t_{\mathrm{w}}) \propto t_{\text{w}}^{\alpha_{t_{\text{w}}}}$ with $\alpha_{t_{\text{w}}} \simeq -1.75$ and $N(E)\text{d}E \propto E^{\alpha_{E}}\text{d}E$ with $\alpha_{E} \simeq -1.67$, respectively. These properties are consistent with the observations of FRB 121102.