Constraining the ellipticity of new-born magnetar with the observational data of Long gamma-ray bursts

TL;DR

This study uses observational data from long gamma-ray bursts to constrain the properties of newly formed magnetars, particularly their ellipticity, and assesses the detectability of associated gravitational waves with current detectors.

Contribution

It provides the first constraints on magnetar ellipticity from LGRB data and explores the potential for gravitational wave detection linked to these objects.

Findings

Magnetar ellipticity correlates with magnetic field strength and initial spin period.

Predicted gravitational wave signals are likely undetectable with current detectors for typical magnetar parameters.

Detection of GW signals would confirm magnetars as central engines of GRBs.

Abstract

The X-ray plateau emission observed in many Long gamma-ray bursts (LGRBs) has been usually interpreted as the spin-down luminosity of a rapidly spinning, highly magnetized neutron star (millisecond magnetar). If this is true, then the magnetar may emit extended gravitational wave (GW) emission associated with the X-ray plateau due to non-axisymmetric deformation or various stellar oscillations. The advanced LIGO and Virgo detectors have searched for long-duration GW transients for several years, no evidence of GWs from any magnetar has been found until now. In this work, we attempt to search for signature of GW radiation in the electromagnetic observation of 30 LGRBs under the assumption of the magnetar model. We utilize the observations of the LGRB plateau to constrain the properties of the new-born magnetar, including the initial spin period $P_0$, diploe magnetic field strength $B_p$ and the ellipticity $\epsilon$. We find that there are some tight relations between magnetar parameters, e.g., $\epsilon \propto B_p^{1.29}$ and $B_p\propto P_0^{1.14}$. In addition, we derive the GW strain for magnetar sample via their spin-down processes, and find that the GWs from these objects may not be detectable by the aLIGO and ET detectors. For a rapidly spinning magnetar ($P\sim 1\mbox{ ms}$, $ B \sim10^{15}\mbox{ G}$), the detection horizon for advanced LIGO O5 detector is $\sim 180\mbox{ Mpc}$. The detection of such GW signal associated with the X-ray plateau would be a smoking gun that the central engine of GRB is a magnetar.