Periodic Fast Radio Bursts from Young Neutron Stars

TL;DR

This paper explores the hypothesis that some repeating fast radio bursts originate from young, highly spinning neutron stars emitting periodic bursts, and discusses observational tests to identify such PFRBs.

Contribution

It introduces the concept of periodic FRBs from young neutron stars, calculates their expected rate and lifetime, and proposes observational signatures to distinguish them from other FRB sources.

Findings

Each young NS emits ~100 bursts over ~100 years.

PFRBs' periods increase and luminosity decreases over time due to spin-down.

FRB 180814's inter-pulse separation could indicate a PFRB origin.

Abstract

Fast radio bursts (FRBs) are highly energetic radio pulses from cosmological origins. Despite an abundance of detections, their nature remains elusive. At least a subset of FRBs is expected to repeat, as the daily FRB rate surpasses that of any known cataclysmic event, which has been confirmed by observations. One of the proposed mechanisms to generate repeating FRBs is supergiant pulses from young and highly spinning NSs, in which case FRBs could inherit the periodicity of their parent NS. Here we examine the consequences of such a population of periodic fast radio bursts (PFRBs). We calculate the rate and lifetime of PFRB progenitors, and find that each newly born highly spinning NS has to emit a number $N_{\rm PFRB}\sim 10^2$ of bursts during its active lifetime of $\tau\sim 100$ years, after which it becomes too dim and crosses a PFRB "death line" analogous to the pulsar one. We propose several tests of this hypothesis. First, the period of PFRBs would increase over time, and their luminosity would decrease, due to the NS spin-down. Second, PFRBs may show modest amounts of rotation measure, given the lack of expelled matter from the pulsar, as opposed to the magnetar-sourced FRBs proposed to explain the first repeater FRB 121102. As an example, we study whether the second confirmed repeater (FRB 180814) is a PFRB, given the preference for an inter-pulse separation of 13 ms within its sub-bursts. We show that, if confirmed, this period would place FRB 180814 in a different category as FRB 121102. We develop tests that would identify---and characterize---the prospective population of PFRBs.