Pre-explosive accretion and simmering phases of Type Ia Supernovae

TL;DR

This study investigates the simmering phase of Type Ia supernova progenitors, revealing that convection remains confined within the URCA shell, leading to larger carbon consumption and neutronization dependent on initial metallicity, affecting explosion conditions.

Contribution

It provides a new analysis of convective URCA processes during the simmering phase, showing confinement within the URCA shell and implications for explosion density and neutronization.

Findings

Convective core remains confined within the URCA shell.

Larger carbon mass must be burned before explosion occurs.

Neutronization depends on initial metallicity and C+N+O content.

Abstract

In accreting WDs approaching the Chandrasekhar limit, hydrostatic carbon burning precedes the dynamical breakout. During this \textit{simmering} phase, $e-$captures are energetically favored in the central region of the star, while $\beta-$decays are favored more outside, and the two zones are connected by a growing convective instability. We analyze the interplay between weak interactions and convection, the so-called convective URCA process, during the simmering phase of SNe Ia progenitors and its effects on the physical and chemical properties at the explosion epoch. At variance with previous studies, we find that the convective core powered by the carbon burning remains confined within the ${^{21}(Ne,F)}$ URCA shell. As a result, a much larger amount of carbon has to be consumed before the explosion which eventually occurs at larger density than previously estimated. In addition, we find that the extension of the convective core and its average neutronization depend on the the WD progenitor initial metallicity. For the average neutronization in the convective core at the explosion epoch we obtain ${\overline{\eta}_{exp}} = (1.094\pm 0.143)\times 10^{-3} + (9.168\pm 0.677)\times 10^{-2}\times Z$. Outside the convective core, the neutronization is instead determined by the initial amount of C+N+O in the progenitor star. Since S, Ca, Cr and Mn, the elements usually exploited to evaluate the pre-explosive neutronization, are mainly produced outside the heavily neutronized core, the problem of too high metallicity estimated for the progenitors of the historical Tycho and Kepler SNe Ia remains unsolved.