The MONUMENT Experiment: Ordinary Muon Capture studies for 0$\nu\beta\beta$ decay

TL;DR

The MONUMENT experiment investigates ordinary muon capture on isotopes relevant for neutrinoless double-beta decay to improve theoretical models, using precise measurements of capture rates on $^{76}$Se and $^{136}$Ba.

Contribution

It provides a detailed description of the experimental setup, calibration, and analysis methods for measuring muon capture on key isotopes relevant to 0νββ decay.

Findings

Successful measurement of muon capture rates on $^{76}$Se and $^{136}$Ba

Development of a detector setup with high energy and timing resolution

Discussion of future improvements for more precise measurements

Abstract

The MONUMENT experiment measures ordinary muon capture (OMC) on isotopes relevant for neutrinoless double-beta (0$\nu\beta\beta$) decay and nuclear astrophysics. OMC is a particularly attractive tool for improving the theoretical description of 0$\nu\beta\beta$ decay. It involves similar momentum transfers and allows testing the virtual transitions involved in 0$\nu\beta\beta$ decay against experimental data. During the 2021 campaign, MONUMENT measured OMC on $^{76}$Se and $^{136}$Ba, the isotopes relevant for next-generation 0$\nu\beta\beta$ decay searches, like LEGEND and nEXO. The experimental setup has been designed to accurately extract the total and partial muon capture rates, which requires precise reconstruction of energies and time-dependent intensities of the OMC-related $\gamma$ rays. The setup also includes a veto counter system to allow selecting a clean sample of OMC events. This work provides a detailed description of the MONUMENT setup operated during the 2021 campaign, its two DAQ systems, calibration and analysis approaches, and summarises the achieved detector performance. Future improvements are also discussed.