Nuclear inputs of key iron isotopes for core-collapse modeling and simulation

TL;DR

This paper provides detailed nuclear data on iron isotopes, including Gamow-Teller strength distributions and electron capture rates, to improve the accuracy of core-collapse supernova models.

Contribution

It offers new microscopic calculations and comparisons for iron isotope nuclear inputs crucial for presupernova evolution simulations.

Findings

Calculated Gamow-Teller strength distributions for iron isotopes.

Provided electron capture and neutrino cooling rates for modeling.

Comparison with other models and experimental data.

Abstract

From the modeling and simulation results of presupernova evolution of massive stars, it was found that isotopes of iron, $^{54,55,56}$Fe, play a significant role inside the stellar cores, primarily decreasing the electron-to-baryon ratio ($Y_{e}$) mainly via electron capture processes thereby reducing the pressure support. The neutrinos produced, as a result of these capture processes, are transparent to the stellar matter and assist in cooling the core thereby reducing the entropy. The structure of the presupernova star is altered both by the changes in $Y_{e}$ and the entropy of the core material. Here we present the microscopic calculation of Gamow-Teller strength distributions for isotopes of iron. The calculation is also compared with other theoretical models and experimental data. Presented also are stellar electron capture rates and associated neutrino cooling rates, due to isotopes of iron, in a form suitable for simulation and modeling codes. It is hoped that the nuclear inputs presented here should assist core-collapse simulators in the process of fine-tuning of the $Y_{e}$ parameter during various phases of presupernova evolution of massive stars. A reliable and accurate time evolution of this parameter is a possible key to generate a successful explosion in modeling of core-collapse supernovae.