A Unified Energy-Reservoir Model Containing Contributions from $^{56}$Ni and Neutron Stars and Its Implication to Luminous Type Ic Supernovae

TL;DR

This paper introduces a unified model combining $^{56}$Ni and neutron star contributions to explain luminous Type Ic supernovae, highlighting the importance of both factors in intermediate luminosity cases.

Contribution

It proposes a hybrid model that accounts for both $^{56}$Ni and neutron star energy contributions, improving understanding of luminous Type Ic supernovae.

Findings

Hybrid models fit observed supernovae better than pure $^{56}$Ni or magnetar models.

Pure $^{56}$Ni models yield unrealistic $^{56}$Ni to ejecta mass ratios.

Future observations can constrain $^{56}$Ni yields and magnetar parameters.

Abstract

Most type-Ic core-collapse supernovae (CCSNe) produce $^{56}$Ni and neutron stars (NSs) or black holes (BHs). The dipole radiation of nascent NSs has usually been neglected in explaining supernovae (SNe) with peak absolute magnitude $M_{\rm peak}$ in any band are $\gtrsim -19.5$~mag, while the $^{56}$Ni can be neglected in fitting most type-Ic superluminous supernovae (SLSNe Ic) whose $M_{\rm peak}$ in any band are $\lesssim -21$~mag, since the luminosity from a magnetar (highly magnetized NS) can outshine that from a moderate amount of $^{56}$Ni. For luminous SNe Ic with $-21 \lesssim M_{\rm peak}\lesssim -19.5$~mag, however, both contributions from $^{56}$Ni and NSs cannot be neglected without serious modeling, since they are not SLSNe and the $^{56}$Ni mass could be up to $\sim 0.5 M_{\odot}$. In this paper we propose a unified model that contain contributions from both $^{56}$Ni and a nascent NS. We select three luminous SNe Ic-BL, SN~2010ay, SN~2006nx, and SN~14475, and show that, if these SNe are powered by $^{56}$Ni, the ratio of $M_{\rm Ni}$ to $M_{\rm ej}$ are unrealistic. Alternatively, we invoke the magnetar model and the hybrid ($^{56}$Ni + NS) model and find that they can fit the observations, indicating that our models are valid and necessary for luminous SNe Ic. Owing to the lack of late-time photometric data, we cannot break the parameter degeneracy and thus distinguish among the model parameters, but we can expect that future multi-epoch observations of luminous SNe can provide stringent constraints on $^{56}$Ni yields and the parameters of putative magnetars.