Observing superluminous supernovae and long gamma ray bursts as potential birthplaces of repeating fast radio bursts

TL;DR

This study investigates whether superluminous supernovae and long gamma-ray bursts could be birthplaces of repeating fast radio bursts by conducting radio observations and analyzing burst probabilities, finding no detections but providing insights into burst detectability.

Contribution

The paper presents the first targeted radio observations of SLSNe and LGRBs for repeating FRBs and models burst probabilities using Weibull distributions, offering new constraints on their connection.

Findings

No bursts detected in 63 hours of observations.

Probabilities of detecting bursts depend on burst distribution and beaming fraction.

Survey strategy impacts burst detection likelihood.

Abstract

Superluminous supernovae (SLSNe) and long gamma ray bursts (LGRBs) have been proposed as progenitors of repeating Fast Radio Bursts (FRBs). In this scenario, bursts originate from the interaction between a young magnetar and its surrounding supernova remnant (SNR). Such a model could explain the repeating, apparently non-Poissonian nature of FRB121102, which appears to display quiescent and active phases. This bursting behaviour is better explained with a Weibull distribution, which includes parametrisation for clustering. We observed 10 SLSNe/LGRBs for 63 hours, looking for repeating FRBs with the Effelsberg-100 m radio telescope, but have not detected any bursts. We scale the burst rate of FRB121102 to an FRB121102-like source inhabiting each of our observed targets, and compare this rate to our upper burst rate limit on a source by source basis. By adopting a fiducial beaming fraction of 0.6, we obtain 99.99\% and 83.4\% probabilities that at least one, and at least half of our observed sources are beamed towards us respectively. One of our SLSN targets, PTF10hgi, is coincident with a persistent radio source, making it a possible analogue to FRB121102. We performed further observations on this source using the Effelsberg-100~m and Parkes-64~m radio telescopes. Assuming that PTF10hgi contains an FRB121102-like source, the probabilities of not detecting any bursts from a Weibull distribution during our observations are 14\% and 16\% for Effelsberg and Parkes respectively. We conclude by showing that a survey of many short observations increases burst detection probability for a source with Weibull distributed bursting activity.