The Continuing Story of SN IIb 2013df: New Optical and IR Observations and Analysis

TL;DR

This study provides new optical and IR observations of SN 2013df, revealing detailed spectral features, ejecta properties, and circumstellar interaction, enhancing understanding of Type IIb supernovae evolution.

Contribution

It offers new spectral analysis, identifies high-velocity He I lines, and models ejecta mass and energy, advancing knowledge of SN 2013df's early and late phases.

Findings

High-velocity He I lines identified in early spectra

Ejecta mass estimated at 3.2-4.6 solar masses

Circumstellar interaction observed after one year

Abstract

SN 2013df is a nearby Type IIb supernova that seems to be the spectroscopic twin of the well-known SN 1993J. Previous studies revealed many, but not all interesting properties of this event. Our goal was to add new understanding of both the early and late-time phases of SN 2013df. Our spectral analysis is based on 6 optical spectra obtained with the 9.2m Hobby-Eberly Telescope during the first month after explosion, complemented by a near-infrared spectrum. We applied the SYNAPPS spectral synthesis code to constrain the chemical composition and physical properties of the ejecta. A principal result is the identification of "high-velocity" He I lines in the early spectra of SN 2013df, manifest as the blue component of the double-troughed profile at ~5650 A. This finding, together with the lack of clear separation of H and He lines in velocity space, indicates that both H and He features form at the outer envelope during the early phases. We also obtained ground-based BVRI and g'r'i'z' photometric data up to +45 days and unfiltered measurements with the ROTSE-IIIb telescope up to +168 days. From the modelling of the early-time quasi-bolometric light curve, we find $M_{ej} \sim 3.2-4.6 M_{\odot}$ and $E_{kin} \sim 2.6-2.8 \times 10^{51}$ erg for the initial ejecta mass and the initial kinetic energy, respectively, which agree well with the values derived from the separate modelling of the light-curve tail. Late-time mid-infrared excess indicates circumstellar interaction starting ~1 year after explosion, in accordance with previously published optical, X-ray, and radio data.