Strong Near-Infrared Carbon Absorption in the Transitional Type Ia SN 2015bp

TL;DR

This study reports strong near-infrared carbon absorption in the transitional Type Ia supernova 2015bp, providing insights into explosion mechanisms and the presence of unburned carbon in these supernovae.

Contribution

First comprehensive optical and near-infrared data on SN 2015bp revealing prominent early-time NIR carbon features in a transitional Type Ia supernova.

Findings

NIR C I $ m{1.0693}\, m{ extmu m}$ line detected at early phase

Optical C II $ m{6580} ext{ {A}}$ notch observed early

At least 50% of transitional SNe Ia show unburned carbon features

Abstract

Unburned carbon is potentially a powerful probe of Type Ia supernova (SN) explosion mechanisms. We present comprehensive optical and near-infrared (NIR) data on the "transitional" Type Ia SN 2015bp. An early NIR spectrum ($t = -$9.9 days with respect to B-band maximum) displays a striking C I $\lambda1.0693\,\mu \rm{m}$ line at $11.9 \times 10^3$~km s$^{-1}$, distinct from the prominent Mg II $\lambda1.0927\,\mu \rm{m}$ feature, which weakens toward maximum light. SN 2015bp also displays a clear C II $\lambda6580$A notch early ($t = -10.9$ days) at $13.2 \times 10^3$~km s$^{-1}$, consistent with our NIR carbon detection. At $M_B = -$18.46, SN 2015bp is less luminous than a normal SN Ia and, along with iPTF13ebh, is the second member of the transitional subclass to display prominent early-time NIR carbon absorption. We find it unlikely that the C I feature is misidentified He I $\lambda1.0830\,\mu\rm{m}$ because this feature grows weaker toward maximum light, while the helium line produced in some double-detonation models grows stronger at these times. Intrigued by these strong NIR carbon detections, but lacking NIR data for other SNe Ia, we investigated the incidence of optical carbon in the sample of nine transitional SNe Ia with early-time data ($t \lesssim-$4 days). We find that four display C II $\lambda$6580A, while two others show tentative detections, in line with the SN Ia population as a whole. We conclude that at least $\sim$50% of transitional SNe Ia in our sample do not come from sub-Chandrasekhar mass explosions due to the clear presence of carbon in their NIR and optical spectra.