Prospects of direct detection of $^{48}$V gamma-rays from thermonuclear supernovae

TL;DR

This paper evaluates the potential for detecting gamma-ray lines from the decay of $^{48}$V in thermonuclear supernovae, highlighting observational prospects, current limits, and future detection chances with upcoming gamma-ray missions.

Contribution

It provides the first detailed analysis of $^{48}$V gamma-ray detectability in supernovae, including modeling, observational constraints, and future prospects with planned gamma-ray observatories.

Findings

Current observations exclude large $^{48}$Cr surface production in SN2014J.

Future missions like AMEGO have a 5% chance to detect $^{48}$V gamma-rays.

Detection conditions for $^{48}$V gamma-rays are outlined for upcoming telescopes.

Abstract

Detection of gamma-rays emitted by radioactive isotopes synthesized in stellar explosions can give important insights into the processes that power transients such as supernovae, as well as providing a detailed census of the abundance of different isotope species relevant to the chemical evolution of the Universe. Observations of nearby supernovae have yielded observational proof that $^{57}$Co powered the late-time evolution of SN1987A's lightcurve, and conclusive evidence that $^{56}$Ni and its daughter nuclei power the light curves of Type Ia supernovae. In this paper we describe the prospects for detecting nuclear decay lines associated with the decay of $^{48}$V, the daughter nucleus of $^{48}$Cr, which is expected to be synthesised in large quantities - $M_{\mathrm{Cr}}\sim1.9\times10^{-2}\,\mathrm{M_\odot}$ - in transients initiated by explosive helium burning ($\alpha$-capture) of a thick helium shell. We calculate emergent gamma-ray line fluxes for a simulated explosion model of a thermonuclear explosion of carbon-oxygen white dwarf core of mass $0.45\,M_{\odot}$ surrounded by a thick helium layer of mass $0.21\,M_{\odot}$. We present observational limits on the presence of $^{48}$V in nearby SNe Ia 2014J using the \textit{INTEGRAL} space telescope, excluding a $^{48}$Cr production on the surface of more than $0.1\,\mathrm{M_{\odot}}$. We find that the future gamma-ray mission AMEGO will have an approximately 5 per cent chance of observing $^{48}$V gamma-rays from such events during the currently-planned operational lifetime, based on our birthrate predictions of faint thermonuclear transients. We describe the conditions for a $3\sigma$ detection by the gamma-ray telescopes \textit{INTEGRAL}/SPI, COSI and AMEGO.