Bolometric light curves of aspherical shock breakout

TL;DR

This paper investigates how aspherical shock breakouts in supernovae produce distinct bolometric light curves, revealing longer, fainter initial flashes and extended emission phases, and discusses implications for observed X-ray transients.

Contribution

It introduces a classification of shock breakout light curves based on asphericity and analyzes their properties, contrasting with spherical models and observational data.

Findings

Aspherical breakouts produce longer, fainter initial flashes.

Extended emission phases occur in significantly aspherical cases.

Standard Wolf--Rayet stars cannot explain certain observed X-ray flashes.

Abstract

The shock breakout emission is the first light that emerges from a supernova. In the spherical case it is characterized by a brief UV flash. In an axisymmetric, non-spherical prolate explosion, the shock first breaches the surface along the symmetry axis, then peels around to larger angles, producing a breakout light curve which may differ substantially from the spherically symmetric case. We study the emergence of a non-relativistic, bipolar shock from a spherical star, and estimate the basic properties of the associated bolometric shock breakout signal. We identify four possible classes of breakout light curves, depending on the degree of asphericity. Compared to spherical breakouts, we find that the main distinguishing features of significantly aspherical breakouts are 1) a longer and fainter initial breakout flash and 2) an extended phase of slowly-declining, or even rising, emission which is produced as ejecta flung out by the oblique breakout expand and cool. We find that the breakout flash has a maximum duration of roughly $\sim R_*/v_{\rm bo}$ where $R_*$ is the stellar radius and $v_{\rm bo}$ is the velocity of the fastest-moving ejecta. For a standard Wolf--Rayet progenitor, the duration of the X-ray flash seen in SN 2008D exceeds this limit, and the same holds true for the prompt X-ray emission of low-luminosity GRBs such as GRB 060218. This suggests that these events cannot be explained by an aspherical explosion within a typical Wolf--Rayet star, implying that they originate from non-standard progenitors with larger breakout radii.