Electromagnetic Shower Reconstruction and Energy Validation with Michel Electrons and $\pi^0$ Samples for the Deep-Learning-Based Analyses in MicroBooNE

P. Abratenko,R An,J Anthony,L. Arellano,J. Asaadi,Adi Ashkenazi,S. Balasubramanian,B. Baller,Cris W. Barnes,G. D. Barr,V. Basque,L. Bathe-Peters,O. Benevides Rodrigues,S. Berkman,A. Bhanderi,A. Bhat,M. Bishai,Andrew Blake,T. A. Bolton,J. Y. Book,L. Camilleri,D. Caratelli,I. Caro Terrazas,F. Cavanna,Giuseppe Benedetto Cerati,Yi Chen,D Cianci,Jan Conrad,M. E. Convery,L. Cooper-Troendle,J. I. Crespo-Anadón,M. Del Tutto,S. R. Dennis,P. Detje,A. Devitt,R. Diurba,R. Dorrill,K. E. Duffy,S. A. Dytman,B. Eberly,Antonio Ereditato,John Evans,R. Fine,G.A. Fiorentini-Aguirre,R.S. Fitzpatrick,B.T. Fleming,N. Foppiani,D. Franco,A. P. Furmanski,D. García Gámez,Steven Gardiner,G Ge,S. Gollapinni,O. Goodwin,E. Gramellini,Paul J. Green,H. Greenlee,W. Q. Gu,R. Guenette,P. Guzowski,L. Hagaman,Or Hen,C. Hilgenberg,G. A. Horton-Smith,A. Hourlier,R. Itay,C.W. James,Xiaolu Ji,L. Jiang,J.H. Jo,R. A. Johnson,Y J Jwa,D. Kalra,N. Kamp,N. Kaneshige,G. Karagiorgi,W. Ketchum,M. H. Kirby,T. Kobilarcik,I. Kreslo,I. Lepetic,K Li,Yichen Li,K. Lin,B.R. Littlejohn,W. C. Louis,X. Luo,K Manivannan,C Mariani,D Marsden,Jennifer L. Marshall,D. A. Martinez Caicedo,K. Mason,A. Mastbaum,N. McConkey,V. Meddage,T. Mettler,Kate C. Miller,J. C. Mills,K. P. Mistry,T. A. Mohayai,A. Mogan,J Moon,Margaret M. Mooney,A.F. Moor,C. D. Moore,L. Mora Lepin,J. Mousseau,Michael T. Murphy,D. Naples,A. Navrer Agasson,M. Nebot-Guinot,R. K. Neely,D. A. Newmark,J A Nowak,M Nunes,O. Palamara,V. Paolone,Afroditi Papadopoulou,V. Papavassiliou,S. F. Pate,N. D. Patel,A Paudel,Z. Pavlovic,E. Piasetzky,I. Ponce-Pinto,Sebastien Prince,Xiaohui Qian,J. L. Raaf,Veljko Radeka,A Rafique,M. Reggiani-Guzzo,L Ren,L.C.J. Rice,L.S. Rochester,J. Rodriguez Rondon,M. J. F. Rosenberg,M. Ross-Lonergan,G. Scanavini,D.W. Schmitz,A. Schukraft,W.G. Seligman,M. H. Shaevitz,R. Sharankova,J. Shi,J. R. Sinclair,A. M. Smith,E.L. Snider,M. Soderberg,S. Söldner-Rembold,Panagiotis Spentzouris,Joshua Spitz,M. Stancari,J. St. John,Thomas Strauss,K. Sutton,S. Sword-Fehlberg,A.M. Szelc,William Tang,Kazuhiro Terao,C. Thorpe,D. Totani,M. Toups,Y. T. Tsai,M. A. Uchida,T. L. Usher,W. Van De Pontseele,B. Viren,M Weber,H. Y. Wei,Z. Williams,S. Wolbers,T. Wongjirad,M. Wospakrik,K. Wresilo,N. Wright,Wei Wu,E. Yandel,T. Yang,G. Yarbrough,L.E. Yates,H. W. Yu,G. P. Zeller,J. Zennamo,Chao Zhang

Electromagnetic Shower Reconstruction and Energy Validation with Michel Electrons and $\pi^0$ Samples for the Deep-Learning-Based Analyses in MicroBooNE

2021

This article presents the reconstruction of the electromagnetic activity from electrons and photons (showers) used in the MicroBooNE deep learning-based low energy electron search. The reconstruction algorithm uses a combination of traditional and deep learning-based techniques to estimate shower energies. We validate these predictions using two $\nu_{\mu}$-sourced data samples: charged/neutral current interactions with final state neutral pions and charged current interactions in which the muon stops and decays within the detector producing a Michel electron. Both the neutral pion sample and Michel electron sample demonstrate agreement between data and simulation. Further, the absolute shower energy scale is shown to be consistent with the relevant physical constant of each sample: the neutral pion mass peak and the Michel energy cutoff.

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