Impact of the quenching of $g_{\rm A}$ on the sensitivity of $0\nu\beta\beta$ experiments

TL;DR

This paper investigates how the quenching of the axial-vector coupling constant $g_A$ affects the sensitivity of neutrinoless double beta decay experiments, showing that the impact is less severe than previously thought when using a consistent pnQRPA approach.

Contribution

The study demonstrates that a consistent pnQRPA approach reduces the expected sensitivity loss from quenching of $g_A$ from two orders of magnitude to a factor of 2-6.

Findings

Quenching of $g_A$ could reduce $0 uetaeta$ sensitivity by a factor of 2-6.

Using a consistent pnQRPA approach mitigates the impact of $g_A$ quenching.

The potential for detecting $0 uetaeta$ decay remains more promising than previously estimated.

Abstract

Detection of the neutrinoless $\beta\beta$ ($0\nu\beta\beta$) decay is of high priority in the particle- and neutrino-physics communities. The detectability of this decay mode is strongly influenced by the value of the weak axial-vector coupling constant $g_{\rm A}$. The recent nuclear-model analyses of $\beta$ and $\beta\beta$ decays suggest that the value of $g_{\rm A}$ could be dramatically quenched, reaching ratios of $g^{\rm free}_{\rm A}/g_{\rm A}\approx 4$, where $g^{\rm free}_{\rm A}=1.27$ is the free, neutron-decay, value of $g_{\rm A}$. The effects of this quenching appear devastating for the sensitivity of the present and future $0\nu\beta\beta$ experiments since the 4$th$ power of this ratio scales the $0\nu\beta\beta$ half-lives. This, in turn, could lead to some two orders of magnitude less sensitivity for the $0\nu\beta\beta$ experiments. In the present Letter it is shown that by using a consistent approach to both the two-neutrino $\beta\beta$ and $0\nu\beta\beta$ decays by the proton-neutron quasiparticle random-phase approximation (pnQRPA), the feared two-orders-of-magnitude reduction in the sensitivity of the $0\nu\beta\beta$ experiments actually shrinks to a reduction by factors in the range $2-6$. This certainly has dramatic consequences for the potential to detect the $0\nu\beta\beta$ decay.