Interplay between non-interfering neutrino exchange mechanisms and nuclear matrix elements in $0\nu\beta\beta$ decay

TL;DR

This paper analyzes how different neutrino exchange mechanisms and nuclear matrix element calculations influence the interpretation of neutrinoless double beta decay experiments, highlighting the importance of accurate NME modeling for future discoveries.

Contribution

It provides a comprehensive analysis of non-interfering light and heavy Majorana neutrino contributions to $0 uetaeta$ decay, incorporating recent NME calculations and experimental sensitivities.

Findings

Joint upper bounds on neutrino contributions derived from multiple experiments.

Heavy-to-light NME ratios significantly affect decay mechanism interpretations.

Nuclear uncertainties can bias the inferred neutrino physics from decay signals.

Abstract

We revisit the phenomenology of neutrinoless double beta ($0\nu\beta\beta$) decay mediated by non-interfering exchange of light and heavy Majorana neutrinos, in the context of current and prospective ton-scale experimental searches, as well as of recent calculations of nuclear matrix elements (NME) in different nuclear models. We derive joint upper bounds on the light and heavy contributions to $0\nu\beta\beta$ decay, for different sets of NME, through separate and combined data coming from the following experiments (and isotopes): KamLAND-Zen and EXO (Xe), GERDA, and MAJORANA (Ge) and CUORE (Te). We further consider three proposed projects that could provide, within current bounds, possible $0\nu\beta\beta$ decay signals at $>\!3\sigma$ level with an exposure of 10 ton years: nEXO (Xe), LEGEND (Ge) and CUPID (Mo). Separate and combined (Xe, Ge, Mo) signals are studied for different representative cases and NME sets, and the conditions leading to (non)degenerate light and heavy neutrino mechanisms are discussed. In particular, the role of heavy-to-light NME ratios in different isotopes is highlighted through appropriate graphical representations. By using different sets of "true" and "test" NME as a proxy for nuclear uncertainties, it is shown that the relative contributions of light and heavy neutrino exchange to $0\nu\beta\beta$ signals may be significantly biased in some cases. Implications for theoretical models connecting light and heavy Majorana neutrino masses are also briefly illustrated. These results provide further motivations to improve NME calculations, so as to better exploit the physics potential of future multi-isotope $0\nu\beta\beta$ searches at the ton scale.