Detector signal characterization with a Bayesian network in XENONnT

E. Aprile; K. Abe; S. Ahmed Maouloud; L. Althueser; B. Andrieu; E. Angelino; J. R. Angevaare; V. C. Antochi; D. Antón Martin; F. Arneodo; L. Baudis; A. L. Baxter; M. Bazyk; L. Bellagamba; R. Biondi; A. Bismark; E. J. Brookes; A. Brown; S. Bruenner; G. Bruno; R. Budnik; T. K. Bui; C. Cai; J. M.R. Cardoso; D. Cichon; A. P. Cimental Chavez; A. P. Colijn; J. Conrad; J. J. Cuenca-García; J. P. Cussonneau; V. D'Andrea; M. P. Decowski; P. Di Gangi; S. Di Pede; S. Diglio; K. Eitel; A. Elykov; S. Farrell; A. D. Ferella; C. Ferrari; H. Fischer; M. Flierman; W. Fulgione; C. Fuselli; P. Gaemers; R. Gaior; A. Gallo Rosso; M. Galloway; F. Gao; R. Glade-Beucke; L. Grandi; J. Grigat; H. Guan; M. Guida; R. Hammann; A. Higuera; C. Hils; L. Hoetzsch; N. F. Hood; J. Howlett; M. Iacovacci; Y. Itow; J. Jakob; F. Joerg; A. Joy; N. Kato; M. Kara; P. Kavrigin; S. Kazama; M. Kobayashi; G. Koltman; A. Kopec; F. Kuger; H. Landsman; R. F. Lang; L. Levinson; I. Li; S. Li; S. Liang; S. Lindemann; M. Lindner; K. Liu; J. Loizeau; F. Lombardi; J. Long; J. A.M. Lopes; Y. Ma; C. MacOlino; J. Mahlstedt; A. Mancuso; L. Manenti; F. Marignetti; T. Marrodán Undagoitia; K. Martens; J. Masbou; D. Masson; E. Masson; S. Mastroianni; M. Messina; K. Miuchi; K. Mizukoshi; A. Molinario; S. Moriyama; K. Morå; Y. Mosbacher; M. Murra; J. Müller; K. Ni; U. Oberlack; B. Paetsch; J. Palacio; Q. Pellegrini; R. Peres; C. Peters; J. Pienaar; M. Pierre; V. Pizzella; G. Plante; T. R. Pollmann; J. Qi; J. Qin; D. Ramírez García; R. Singh; L. Sanchez; J. M.F. Dos Santos; I. Sarnoff; G. Sartorelli; J. Schreiner; D. Schulte; P. Schulte; H. Schulze Eißing; M. Schumann; L. Scotto Lavina; M. Selvi; F. Semeria; P. Shagin; S. Shi; E. Shockley; M. Silva; H. Simgen; A. Takeda; P. L. Tan; A. Terliuk; D. Thers; F. Toschi; G. Trinchero; C. Tunnell; F. Tönnies; K. Valerius; G. Volta; C. Weinheimer; M. Weiss; D. Wenz; C. Wittweg; T. Wolf; V. H.S. Wu; Y. Xing; D. Xu; Z. Xu; M. Yamashita; L. Yang; J. Ye; L. Yuan; G. Zavattini; M. Zhong; T. Zhu

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Detector signal characterization with a Bayesian network in XENONnT

Physical Review D (2023) 108(1)

DOI: 10.1103/PhysRevD.108.012016

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Abstract

We developed a detector signal characterization model based on a Bayesian network trained on the waveform attributes generated by a dual-phase xenon time projection chamber. By performing inference on the model, we produced a quantitative metric of signal characterization and demonstrate that this metric can be used to determine whether a detector signal is sourced from a scintillation or an ionization process. We describe the method and its performance on electronic-recoil (ER) data taken during the first science run of the XENONnT dark matter experiment. We demonstrate the first use of a Bayesian network in a waveform-based analysis of detector signals. This method resulted in a 3% increase in ER event-selection efficiency with a simultaneously effective rejection of events outside of the region of interest. The findings of this analysis are consistent with the previous analysis from XENONnT, namely a background-only fit of the ER data.

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Aprile, E., Abe, K., Ahmed Maouloud, S., Althueser, L., Andrieu, B., Angelino, E., … Zhu, T. (2023). Detector signal characterization with a Bayesian network in XENONnT. Physical Review D, 108(1). https://doi.org/10.1103/PhysRevD.108.012016

Detector signal characterization with a Bayesian network in XENONnT

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