Time-Varying Sodium Absorption in the Type Ia Supernova 2013gh

TL;DR

This study investigates early-time sodium absorption line variability in Type Ia supernovae to detect circumstellar matter, revealing small but significant Na I D profile variations indicative of photoionisation or geometric effects.

Contribution

It provides the first early-phase high-resolution spectroscopic observations of SNe Ia to detect time-varying absorption lines, highlighting the importance of early observations for circumstellar matter detection.

Findings

Detected small but significant Na I D profile variations in SN 2013gh.

Variations suggest either geometric effects or photoionisation of circumstellar gas.

Emphasized the need for early-phase observations to study supernova environments.

Abstract

Temporal variability of narrow absorption lines in high-resolution spectra of Type Ia supernovae (SNe Ia) is studied to search for circumstellar matter. Time series which resolve the profiles of absorption lines such as Na I D or Ca II H&K are expected to reveal variations due to photoionisation and subsequent recombination of the gases. The presence, composition, and geometry of circumstellar matter may hint at the elusive progenitor system of SNe Ia and could also affect the observed reddening law. To date, there are few known cases of time-varying Na I D absorption in SNe Ia, all of which occurred during relatively late phases of the supernova evolution. Photoionisation, however, is predicted to occur during the early phases of SNe Ia, when the supernova peaks in the ultraviolet. We therefore attempt to observe early-time absorption-line variations by obtaining high-resolution spectra of SNe before maximum light. We have obtained photometry and high-resolution spectroscopy of SNe Ia 2013gh and iPTF 13dge, to search for absorption- line variations. Furthermore, we study interstellar absorption features in relation to the observed photometric colours of the SNe. Results. Both SNe display deep Na I D and Ca II H&K absorption features. Furthermore, small but significant variations are detected in a feature of the Na I D profile of SN 2013gh. The variations are consistent with either geometric effects of rapidly moving or patchy gas clouds or photoionisation of Na I gas at R \approx 1019 cm from the explosion. Our analysis indicates that it is necessary to focus on early phases to detect photoionisation effects of gases in the circumstellar medium of SNe Ia. Different absorbers such as Na I and Ca II can be used to probe for matter at different distances from the SNe.