Spectropolarimetry of superluminous supernovae: insight into their geometry

TL;DR

This study presents spectropolarimetric observations of a hydrogen-free superluminous supernova, revealing its aspherical geometry and evolution, which provides insights into the explosion mechanism and ejecta structure.

Contribution

First spectropolarimetric analysis of a superluminous supernova, demonstrating its aspherical ejecta and potential central engine influence.

Findings

Significant polarization observed at two epochs.

Ejecta geometry consistent with an axi-symmetric ellipsoid.

Wavelength-dependent polarization suggests line opacity effects.

Abstract

We present the first spectropolarimetric observations of a hydrogen-free superluminous supernova at z=0.1136, namely SN 2015bn. The transient shows significant polarization at both the observed epochs: one 24 days before maximum light in the rest-frame, and the subsequent at 27 days after peak luminosity. Analysis of the Q-U plane suggests the presence of a dominant axis and no physical departure from the main axis at either epoch. The polarization spectrum along the dominant axis is characterized by a strong wavelength dependence and an increase in the signal from the first to the second epoch. We use a Monte Carlo code to demonstrate that these properties are consistent with a simple toy model that adopts an axi-symmetric ellipsoidal configuration for the ejecta. We find that the wavelength dependence of the polarisation is possibly due to a strong wavelength dependence in the line opacity, while the higher level of polarisation at the second epoch is a consequence of the increase in the asphericity of the inner layers of the ejecta or the fact that the photosphere recedes into less spherical layers. The geometry of the superluminous supernova results similar to those of stripped-envelope core collapse SNe connected with GRB, while the overall evolution of the ejecta shape could be consistent with a central engine.