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arxiv: 2504.15464 · v3 · pith:G4WME7ZY · submitted 2025-04-21 · physics.ins-det · hep-ex

Ultra-sensitive radon assay using an electrostatic chamber in a recirculating system

nEXO Collaboration: A. Anker , P. A. Breur , B. Mong , P. Acharya , A. Amy , E. Angelico , I. J. Arnquist , A. Atencio
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classification physics.ins-det hep-ex
keywords radondetectionemanationexperimentsmaterialsassaybackgroundchamber
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Rare event searches such as neutrinoless double beta decay and Weakly Interacting Massive Particle detection require ultra-low background detectors. Radon contamination is a significant challenge for these experiments, which employ highly sensitive radon assay techniques to identify and select low-emission materials. This work presents the development of ultra-sensitive electrostatic chamber (ESC) instruments designed to measure radon emanation in a recirculating gas loop, for future lower background experiments. Unlike traditional methods that separate emanation and detection steps, this system allows continuous radon transport and detection. This is made possible with a custom-built recirculation pump. A Python-based analysis framework, PyDAn, was developed to process and fit time-dependent radon decay data. Radon emanation rates are given for various materials measured with this instrument. A radon source of known activity provides an absolute calibration, enabling statistically-limited minimal detectable activities of 20 $\mu$Bq. These devices are powerful tools for screening materials in the development of low-background particle physics experiments.

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