Search for the in-situ production of $^{77}$Ge in the GERDA neutrinoless double-beta decay experiment

TL;DR

This study searched for in-situ production of $^{77}$Ge in GERDA's neutrinoless double-beta decay experiment, setting upper limits that support previous predictions and suggesting background suppression methods for future experiments.

Contribution

It provides the first experimental upper limit on $^{77}$Ge production in GERDA, validating prior Monte Carlo predictions and proposing tagging techniques to reduce background in future searches.

Findings

No $^{77}$Ge signal observed in GERDA data.

Upper limit on production rate set at <0.216 nuc/(kg·yr).

Results support previous Monte Carlo predictions.

Abstract

The beta decay of $^{77}$Ge and $^{77\mathrm{m}}$Ge, both produced by neutron capture on $^{76}$Ge, is a potential background for Germanium based neutrinoless double-beta decay search experiments such as GERDA or the LEGEND experiment. In this work we present a search for $^{77}$Ge decays in the full GERDA Phase II data set. A delayed coincidence method was employed to identify the decay of $^{77}$Ge via the isomeric state of $^{77}$As (9/2$^+$, 475 keV, ${T_{1/2} = 114}\,\mu $s, $^{77\mathrm{m}}$As). New digital signal processing methods were employed to select and analyze pile-up signals. No signal was observed, and an upper limit on the production rate of was set at $<0.216$ nuc/(kg$\cdot$yr) (90% CL). This corresponds to a total production rate of $^{77}$Ge and $^{77\mathrm{m}}$Ge of $<0.38$ nuc/(kg$\cdot$ yr) (90% CL), assuming equal production rates. A previous Monte Carlo study predicted a value for in-situ $^{77}$Ge and $^{77\mathrm{m}}$Ge production of (0.21$\pm$0.07) nuc/(kg$\cdot$yr), a prediction that is now further corroborated by our experimental limit. Moreover, tagging the isomeric state of $^{77\mathrm{m}}$As can be utilised to further suppress the $^{77}$Ge background. Considering the similar experimental configurations of LEGEND-1000 and GERDA, the cosmogenic background in LEGEND-1000 at LNGS is estimated to remain at a sub-dominant level.