Interpretable machine learning approach for electron antineutrino selection in a large liquid scintillator detector

Gavrikov, A.; Cerrone, V.; Serafini, A.; Brugnera, R.; Garfagnini, A.; Grassi, M.; Jelmini, B.; Lastrucci, L.; Aiello, S.; Andronico, G.; Antonelli, V.; Barresi, A.; Basilico, D.; Beretta, M.; Bergnoli, A.; Borghesi, M.; Brigatti, A.; Bruno, R.; Budano, A.; Caccianiga, B.; Cammi, A.; Caruso, R.; Chiesa, D.; Clementi, C.; Dusini, S.; Fabbri, A.; Felici, G.; Ferraro, F.; Giammarchi, M.G.; Giudice, N.; Guizzetti, R.M.; Guardone, N.; Landini, C.; Lippi, I.; Loffredo, S.; Loi, L.; Lombardi, P.; Lombardo, C.; Mantovani, F.; Mari, S.M.; Martini, A.; Miramonti, L.; Montuschi, M.; Nastasi, M.; Orestano, D.; Ortica, F.; Paoloni, A.; Percalli, E.; Petrucci, F.; Previtali, E.; Ranucci, G.; Re, A.C.; Redchuck, M.; Ricci, B.; Romani, A.; Saggese, P.; Sava, G.; Sirignano, C.; Sisti, M.; Stanco, L.; Stanescu Farilla, E.; Strati, V.; Torri, M.D.C.; Triossi, A.; Tuvè, C.; Venettacci, C.; Verde, G.; Votano, L.

doi:10.1016/j.physletb.2024.139141

Several neutrino detectors, KamLAND, Daya Bay, Double Chooz, RENO, and the forthcoming large-scale JUNO, rely on liquid scintillator to detect reactor antineutrino interactions. In this context, inverse beta decay represents the golden channel for antineutrino detection, providing a pair of correlated events, thus a strong experimental signature to distinguish the signal from a variety of backgrounds. However, given the low cross-section of antineutrino interactions, the development of a powerful event selection algorithm becomes imperative to achieve effective discrimination between signal and backgrounds. In this study, we introduce a machine learning (ML) model to achieve this goal: a fully connected neural network as a powerful signal-background discriminator for a large liquid scintillator detector. We demonstrate, using the JUNO detector as an example, that, despite the already high efficiency of a cut-based approach, the presented ML model can further improve the overall event selection efficiency. Moreover, it allows for the retention of signal events at the detector edges that would otherwise be rejected because of the overwhelming amount of background events in that region. We also present the first interpretable analysis of the ML approach for event selection in reactor neutrino experiments. This method provides insights into the decision-making process of the model and offers valuable information for improving and updating traditional event selection approaches.

Interpretable machine learning approach for electron antineutrino selection in a large liquid scintillator detector / A. Gavrikov, V. Cerrone, A. Serafini, R. Brugnera, A. Garfagnini, M. Grassi, B. Jelmini, L. Lastrucci, S. Aiello, G. Andronico, V. Antonelli, A. Barresi, D. Basilico, M. Beretta, A. Bergnoli, M. Borghesi, A. Brigatti, R. Bruno, A. Budano, B. Caccianiga, A. Cammi, R. Caruso, D. Chiesa, C. Clementi, S. Dusini, A. Fabbri, G. Felici, F. Ferraro, M.G. Giammarchi, N. Giudice, R.M. Guizzetti, N. Guardone, C. Landini, I. Lippi, S. Loffredo, L. Loi, P. Lombardi, C. Lombardo, F. Mantovani, S.M. Mari, A. Martini, L. Miramonti, M. Montuschi, M. Nastasi, D. Orestano, F. Ortica, A. Paoloni, E. Percalli, F. Petrucci, E. Previtali, G. Ranucci, A.C. Re, M. Redchuck, B. Ricci, A. Romani, P. Saggese, G. Sava, C. Sirignano, M. Sisti, L. Stanco, E. Stanescu Farilla, V. Strati, M.D.C. Torri, A. Triossi, C. Tuvè, C. Venettacci, G. Verde, L. Votano. - In: PHYSICS LETTERS. SECTION B. - ISSN 0370-2693. - 860:(2025 Jan), pp. 139141.1-139141.13. [10.1016/j.physletb.2024.139141]

Interpretable machine learning approach for electron antineutrino selection in a large liquid scintillator detector

Gavrikov, A.;Cerrone, V.;Serafini, A.;Brugnera, R.;Garfagnini, A.;Grassi, M.;Jelmini, B.;Lastrucci, L.;Aiello, S.;Andronico, G.;V. Antonelli;Barresi, A.;D. Basilico;M. Beretta;Bergnoli, A.;Borghesi, M.;Brigatti, A.;Bruno, R.;Budano, A.;B. Caccianiga;Cammi, A.;Caruso, R.;Chiesa, D.;Clementi, C.;Dusini, S.;Fabbri, A.;Felici, G.;Ferraro, F.;M.G. Giammarchi;Giudice, N.;Guizzetti, R. M.;Guardone, N.;Landini, C.;Lippi, I.;Loffredo, S.;Loi, L.;Lombardi, P.;Lombardo, C.;Mantovani, F.;Mari, S. M.;Martini, A.;L. Miramonti;Montuschi, M.;Nastasi, M.;Orestano, D.;Ortica, F.;Paoloni, A.;E. Percalli;Petrucci, F.;Previtali, E.;Ranucci, G.;A.C. Re;Redchuck, M.;Ricci, B.;Romani, A.;Saggese, P.;Sava, G.;Sirignano, C.;Sisti, M.;Stanco, L.;Stanescu Farilla, E.;Strati, V.;M.D.C. Torri;Triossi, A.;Tuvè, C.;Venettacci, C.;Verde, G.;Votano, L.

2025

Abstract

Several neutrino detectors, KamLAND, Daya Bay, Double Chooz, RENO, and the forthcoming large-scale JUNO, rely on liquid scintillator to detect reactor antineutrino interactions. In this context, inverse beta decay represents the golden channel for antineutrino detection, providing a pair of correlated events, thus a strong experimental signature to distinguish the signal from a variety of backgrounds. However, given the low cross-section of antineutrino interactions, the development of a powerful event selection algorithm becomes imperative to achieve effective discrimination between signal and backgrounds. In this study, we introduce a machine learning (ML) model to achieve this goal: a fully connected neural network as a powerful signal-background discriminator for a large liquid scintillator detector. We demonstrate, using the JUNO detector as an example, that, despite the already high efficiency of a cut-based approach, the presented ML model can further improve the overall event selection efficiency. Moreover, it allows for the retention of signal events at the detector edges that would otherwise be rejected because of the overwhelming amount of background events in that region. We also present the first interpretable analysis of the ML approach for event selection in reactor neutrino experiments. This method provides insights into the decision-making process of the model and offers valuable information for improving and updating traditional event selection approaches.

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	Parole chiave
	
				Event selection; Interpretability; Machine learning; Neutrino physics;
			
	Settori scientifico-disciplinari dell'articolo (validi dal 09/05/2024)
	
				Settore PHYS-01/A - Fisica sperimentale delle interazioni fondamentali e applicazioni
			
	Titolo del progetto
	
	Titolo Progetto
	
									UNIPhD - Eight century legacy of multidisciplinary research and training for the next-generation talents
								
	Acronimo
	
									UNIPhD
								
	Nome finanziatore
	
										European Commission
									
	Finanziamento
	
									Horizon 2020 Framework Programme
								
	N. Contratto
	
									101034319
								
	Data di pubblicazione
	
				gen-2025
			
	Data ahead of print o data di stampa
	
				19-nov-2024
			
	Rivista in ANCE
	
				PHYSICS LETTERS. SECTION B
			
	DOI
	
				https://dx.doi.org/10.1016/j.physletb.2024.139141
			
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				Article (author)
			
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				01 - Articolo su periodico

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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/2434/1119255

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