Abstract

Much controversy surrounds the inferred progenitor masses of type-II-Plateau (II-P) supernovae (SNe). The debate is nourished by the discrepant results from radiation-hydrodynamics simulations, pre-explosion imaging, and studies of host stellar populations. Here, we present a controlled experiment using four solar-metallicity models with zero-age main sequence masses of 12, 15, 20, and 25 M⊙. Because of the effects of core burning and surface mass loss, these models reach core collapse as red-supergiant (RSG) stars with a similar H-rich envelope mass of 8 to 9 M⊙ but with final masses in the range 11 to 16 M⊙. We explode the progenitors using a thermal bomb, adjusting the energy deposition to yield an asymptotic ejecta kinetic energy of 1.25 × 1051 erg and an initial 56Ni mass of 0.04 M⊙. The resulting SNe produce similar photometric and spectroscopic properties from 10 to 200 d. The spectral characteristics are degenerate. The scatter in early-time color results from the range in progenitor radii, while the differences in late-time spectra reflect the larger oxygen yields in more massive progenitors. Because the progenitors have a comparable H-rich envelope mass, the photospheric phase duration is comparable for all models; the difference in He-core mass is invisible. As different main sequence masses can produce progenitors with a similar H-rich envelope mass, light-curve modeling cannot provide a robust and unique solution for the ejecta mass of type-II-P SNe. The numerous uncertainties in massive-star evolution and wind-mass loss also prevent a robust association with a main sequence star mass. Light-curve modeling can at best propose compatibility.

Highlights

  • Understanding how the landscape of type-II-Plateau (II-P) supernova (SN) properties connects to the diversity of redsupergiant (RSG) star progenitors and their explosion is of great interest for astrophysics

  • Discrepant estimates of the ejecta and progenitor masses are often obtained from radiation-hydrodynamics simulations that study the bolometric light-curve evolution1, from pre-explosion imaging, and from studies of host stellar populations

  • While significant advances have been made in the modeling of the proto-neutron star phase leading to shock revival and explosion in massive star progenitors, there are still many unresolved issues

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Summary

Introduction

Understanding how the landscape of type-II-Plateau (II-P) supernova (SN) properties connects to the diversity of redsupergiant (RSG) star progenitors and their explosion is of great interest for astrophysics. The ejecta properties in these studies are broadly consistent with inferred properties from type-II-P SN observations (Lentz et al 2015; Müller et al 2017; Glas et al 2019; O’Connor & Couch 2018; Vartanyan et al 2019), the simulations cannot predict which stars produce core-collapse SNe, or quantities such as the 56Ni mass and explosion energy.

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