SN 2023zcu: A Type IIP SN with Early Flash Features

Abstract

We present a detailed photometric and spectroscopic analysis of the Type IIP supernova SN~2023zcu, which exploded in the galaxy NGC~2139 (redshift z = 0.006). SN~2023zcu exhibits a well-sampled light curve covering the rise, plateau, and nebular phases. It has an optically thick phase of 100.6 0.6 d with a magnitude drop of 1.7 mag in the V band during the transition between the plateau and the nebular phases. Weak emission features in the early-time spectra indicate a low-level interaction between circumstellar material (CSM) and the SN ejecta. The spectral evolution is well sampled and exhibits a prominent P-Cygni profile of Hα, a defining characteristic of Type IIP SNe. Signatures of metal-line formation (e.g., Fe2, Ca2 near-infrared triplet) are also evident in the spectra as the SN evolves. Spectral modeling with the radiative-transfer code TARDIS during the early photospheric phase (8.7--35.5 d since explosion) yields photospheric temperatures decreasing from 9,000 to 6,000 K and expansion velocities declining from 10,000 to 5,400 km s-1. A tailored expanding photosphere method (EPM) fit based on the TARDIS models provides a distance estimate of 27.8 2.0 Mpc. Nebular-phase spectra and bolometric light-curve modeling suggest a progenitor mass in the range 12--15 M. This thorough analysis helps to constrain progenitor properties and explosion parameters, thereby strengthening our understanding of Type IIP SNe.