$\gamma\gamma$ decay as a probe of neutrinoless $\beta\beta$ decay nuclear matrix elements

TL;DR

This study finds a strong linear correlation between gamma-gamma decay nuclear matrix elements and neutrinoless double-beta decay NMEs across various nuclei, suggesting gamma-gamma decay measurements could help constrain key parameters in fundamental physics.

Contribution

The paper demonstrates, through large-scale shell model calculations, that gamma-gamma decay NMEs are linearly correlated with neutrinoless double-beta decay NMEs, offering a new experimental avenue to constrain these quantities.

Findings

Good linear correlation between gamma-gamma and 0νββ NMEs.

Correlation holds for spin and orbital driven gamma transitions.

Potential for gamma-gamma measurements to constrain 0νββ NMEs.

Abstract

We study double gamma ($\gamma\gamma$) decay nuclear matrix elements (NMEs) for a wide range of nuclei from titanium to xenon, and explore their relation to neutrinoless double-beta ($0\nu\beta\beta$) NMEs. To favor the comparison, we focus on double-magnetic dipole transitions in the final $\beta\beta$ nuclei, in particular the $\gamma\gamma$ decay of the double isobaric analog of the initial $\beta\beta$ state into the ground state. For the decay with equal-energy photons, our large-scale nuclear shell model results show a good linear correlation between the $\gamma\gamma$ and $0\nu\beta\beta$ NMEs. Our analysis reveals that the correlation holds for $\gamma\gamma$ transitions driven by the spin or orbital angular momentum due to the dominance of zero-coupled nucleon pairs, a feature common to $0\nu\beta\beta$ decay. Our shell-model findings point out the potential of future $\gamma\gamma$ decay measurements to constrain $0\nu\beta\beta$ NMEs, which are key to answer fundamental physics questions based on $0\nu\beta\beta$ experiments.