Early color photometry of a possible type Iax supernova 2023mnc: inferring the distance and progenitor constraints

Author(s)

Yang, Thomas Z.; Zhang, Maureen; Shen, Tianran; Jiang, Justin; Faison, Michael; Warrener, Michael; Zheng, Tai; ... Show more Show less

Abstract

Abstract Early-time radioactive signals from type Ia supernovae (SNeIa) can provide important constraints on the explosion mechanism and the progenitor system. We present observations and analysis of SN 2023mnc, a SN Ia, ∼ 7 $\sim 7$ days following its discovery. Follow-up observations were conducted in optical bands, covering phases from ∼ − 4 $\sim -4$ days to ∼ 15 $\sim 15$ days relative to its r-band peak luminosity. The early photometry allows us to estimate the physical properties of the ejecta and characterize the possible divergence from a normal SN Ia; we were able to characterize it as a Type Iax supernova instead. The estimated date of explosion is t 0 = 60130 $t_{0}=60130$ MJD and implies a short rise time of t r i s e ≈ 16 $t_{rise} \approx 16$ days. The apparent g-band peak magnitude and the post-peak decline rate are m m a x ( g ) = − 19.52 ± 0.47 $m_{max}(g)=-19.52\pm 0.47$ mag and Δ m 15 ( g ) = 0.825 ± 1.635 $\Delta m_{15}(g)=0.825\pm 1.635$ mag, respectively. Based on the light curve fitting of standard SN Ia models, the distance modulus is predicted to be 37.98 ± 0.207 $37.98\pm 0.207$ mag for g-band measurements, and the SN is predicted to be 394.46 ± 38 $394.46\pm 38$ Mpc from Earth. Assuming a 56Ni powered radiative diffusion, the estimated bolometric light-curve peaks at 3.8 × 10 41 $3.8 \times 10^{41}$ erg s−1 and indicates that only 0.017 M ⊙ $0.017 M_{\odot }$ of 56Ni was produced, making SN 2023mnc a moderate luminosity object in the Iax class with peak absolute magnitude of M V = − 15.3 $M_{V}=-15.3$ mag. Comparing the observed color evolution with the predicted by different models such as deflagration-to-detonation transition and pure-deflagration scenario, the latter one is favored. The photometry of SN 2023mnc offers a unique opportunity to examine the progenitor systems and ignition process of the SNe Iax, adding weight to the population study of such sub-class SNe.

Date issued

2023-11-07

URI

https://hdl.handle.net/1721.1/152924

Department

Massachusetts Institute of Technology. Department of Aeronautics and Astronautics

Publisher

Springer Netherlands

Citation

Astrophysics and Space Science. 2023 Nov 07;368(11):93

Version: Author's final manuscript