Periodic Activities of Fast Radio Burst Repeaters from Precessing Magnetars with Evolving Obliquity

TL;DR

This paper models magnetar precession and obliquity evolution to explain the periodic activities of FRB repeaters and SGRs, linking their ages and emission patterns to observable periodic signals.

Contribution

It presents a self-consistent model of magnetar rotation and precession evolution, connecting periodic FRB activities to magnetar age and emission geometry.

Findings

Magnetar ages are constrained to hundreds to tens of thousands of years.

Observable probability of FRB activity varies with magnetar age.

Multiple active windows per precession cycle could be observed.

Abstract

Fast radio bursts (FRBs) are cosmological radio transients with millisecond durations and extremely high brightness temperatures. One FRB repeater, FRB 180916.J0158+65 (FRB 180916B), was confirmed to appear 16.35-day periodic activities with 5-day activity window. Another FRB repeater, FRB 121102, and two soft gamma-ray repeaters (SGRs), SGR 1935+2154 and SGR 1806-20, also show possible periodic activities. These periodicities might originate from the precession process of young magnetars due to the anisotropic pressure from the inner magnetic fields as proposed in the literature. In this work, we analyze a self-consistent model for the rotation evolution of magnetars and obtain the evolutions of magnetar precession and obliquity. We find that if the FRB repeaters and the SGRs with (possible) periodic activities originate from the magnetar precession, their ages would be constrained to be hundreds to tens of thousands of years, which is consistent with the typical ages of magnetars. Assuming that the FRB emission is beaming in the magnetosphere as proposed in the literature, we calculate the evolution of the observable probability and the duty cycle of the active window period. We find that for a given magnetar the observable probability increases with the magnetar age in the early stage and decreases with the magnetar age in the later stage, meanwhile, there are one or two active windows in one precession period if the emission is not perfectly axisymmetric with respect to the deformation axis of a magnetar, which could be tested by the future observation for repeating FRB sources.