Design, Calibration, and Performance of the MINERvA Detector

L. Aliaga; L. Bagby; B. Baldin; A. Baumbaugh; A. Bodek; R. Bradford,; W.K. Brooks; D. Boehnlein; S. Boyd; H. Budd; A. Butkevich; D.A. Martinez; Caicedo; C.M. Castromonte; M.E. Christy; J. Chvojka; H. da Motta; D.S.; Damiani; I. Danko; M. Datta; R. DeMaat; J. Devan; E. Draeger; S.A. Dytman,; G.A. Diaz; B. Eberly; D.A. Edmondson; J. Felix; L. Fields; G.A. Fiorentini,; A.M. Gago; H. Gallagher; C.A. George; C. Gingu; B. Gobbi; R. Gran; N.; Grossman; D. A. Harris; J. Heaton; A. Higuera; J.A. Hobbs; I.J. Howley; K.; Hurtado; M. Jerkins; T. Kafka; M.O. Kantner; C. Keppel; J. Kilmer; A.H.; Krajeski; H. Lee; A.G. Leister; G. Locke; G. Maggi; E. Maher; S. Manly; W.A.; Mann; C.M. Marshall; K.S. McFarland; C.L. McGivern; A. M. McGowan; J.G.; Morfin; J. Mousseau; D. Naples; J.K. Nelson; G. Niculescu; I. Niculescu; C.D.; O'Connor; N. Ochoa; J. Olsen; B. Osmanov; J. Osta; J.L. Palomino; V. Paolone,; J. Park; G. N. Perdue; C. Pena; A. Pla-Dalmau; L. Rakotondravohitra; R. D.; Ransome; H. Ray; L.Ren; P. Rubinov; C. Rude; K.E. Sassin; H. Schellman; D.W.; Schmitz; R.M. Schneider; C. Simon; F.D. Snider; M.C. Snyder; C.J. Solano; Salinas; N. Tagg; B.G. Tice; R.N. Tilden; G. Tzanakos; J.P. Velasquez; T.; Walton; A. Westerberg; J. Wolcott; B.A. Wolthuis; N. Woodward; T. Wytock; G.; Zavala; D. Zhang; L.Y. Zhu; and B.P. Ziemer

arXiv:1305.5199·physics.ins-det·March 12, 2014

Design, Calibration, and Performance of the MINERvA Detector

L. Aliaga, L. Bagby, B. Baldin, A. Baumbaugh, A. Bodek, R. Bradford,, W.K. Brooks, D. Boehnlein, S. Boyd, H. Budd, A. Butkevich, D.A. Martinez, Caicedo, C.M. Castromonte, M.E. Christy, J. Chvojka, H. da Motta, D.S., Damiani, I. Danko, M. Datta, R. DeMaat, J. Devan, E. Draeger

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TL;DR

The paper details the design, calibration, and performance evaluation of the MINERvA detector, a segmented scintillator-based system used for precision neutrino-nucleus scattering studies at Fermilab.

Contribution

It provides a comprehensive description of the detector's design, calibration techniques, and operational performance, informing future neutrino detection experiments.

Findings

01

Detector response remains stable over time

02

Effective calibration methods established for scintillator and calorimetry

03

Design facilitates detailed nuclear effects studies in neutrino interactions

Abstract

The MINERvA experiment is designed to perform precision studies of neutrino-nucleus scattering using $ν_{μ}$ and $\overset{ν}{ˉ}_{μ}$ neutrinos incident at 1-20 GeV in the NuMI beam at Fermilab. This article presents a detailed description of the \minerva detector and describes the {\em ex situ} and {\em in situ} techniques employed to characterize the detector and monitor its performance. The detector is comprised of a finely-segmented scintillator-based inner tracking region surrounded by electromagnetic and hadronic sampling calorimetry. The upstream portion of the detector includes planes of graphite, iron and lead interleaved between tracking planes to facilitate the study of nuclear effects in neutrino interactions. Observations concerning the detector response over sustained periods of running are reported. The detector design and methods of operation have relevance to future…

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