Circular polarization of gravitational waves from magnetorotational supernovae

TL;DR

This paper demonstrates that magnetorotational supernovae produce circularly polarized gravitational waves originating from the proto-neutron star, offering a new observational signature for these energetic stellar explosions.

Contribution

It provides the first detailed simulation of GW polarization in magnetorotational supernovae, linking polarization features to PNS dynamics and suggesting detectability with current observatories.

Findings

Strong circular polarization appears along the rotation axis early after core bounce.

GW spectrum peaks at ~90 Hz, related to PNS surface motions.

Polarization signals are within current GW detector sensitivity.

Abstract

Context. Gravitational waves (GW) provide a unique probe of the explosion mechanism of massive stars and the evolution of nascent proto-neutron stars (PNS). Magnetorotational explosions are one of the promising non-canonical core-collapse supernova scenarios, possibly linked to magnetar formation and energetic supernova explosions. However, the GW signatures of such events remain incompletely understood presently. Aims. This study investigates the origin and nature of gravitational-wave polarization arising from a magnetorotational core-collapse model and examines its potential detectability by current gravitational-wave observatories. Methods. We perform a three-dimensional simulation of general-relativistic magnetohydrodynamics of a rapidly rotating, strongly magnetized 20 M$_\odot$ progenitor, including multi-energy neutrino transport. The polarization states of the GW signals are analyzed with Stokes parameters. Results. We find that strong circular polarization emerges along the rotation axis during the early post-bounce phase (<230 ms after core bounce). The characteristic GW spectrum peaks at ~90 Hz, consistent with the emission at twice the local angular velocity (~45 Hz) around the PNS surface at cylindrical radii of ~50 km. These features are attributed to the low-T/|W| instabilities and non-axisymmetric motions near the PNS, rather than to the magnetohydrodynamic jets themselves. The polarization signals lie within the sensitivity bands of current GW detectors. Conclusions. Our study demonstrates that models launching magnetorotationally driven jets can produce circularly polarized GW signals originating from the inner PNS region. This provides an observational signature that complements previous findings from non-magnetized rotating models. Thus, our novel findings establish that the GW polarization is a promising diagnostic of non-canonical core-collapse supernovae.