Validation of GEANT4 Monte Carlo models with a highly granular scintillator-steel hadron calorimeter

C. Adloff; J. Blaha; J. J. Blaising; C. Drancourt; A. Espargilière; R. Gaglione; N. Geffroy; Y. Karyotakis; J. Prast; G. Vouters; K. Francis; J. Repond; J. Schlereth; J. Smith; L. Xia; E. Baldolemar; J. Li; S. T. Park; M. Sosebee; A. P. White; J. Yu; T. Buanes; G. Eigen; Y. Mikami; N. K. Watson; G. Mavromanolakis; M. A. Thomson; D. R. Ward; W. Yan; D. Benchekroun; A. Hoummada; Y. Khoulaki; J. Apostolakis; A. Dotti; G. Folger; V. Ivantchenko; V. Uzhinskiy; M. Benyamna; C. Cârloganu; F. Fehr; P. Gay; S. Manen; L. Royer; G. C. Blazey; A. Dyshkant; J. G.R. Lima; V. Zutshi; J. Y. Hostachy; L. Morin; U. Cornett; D. David; G. Falley; K. Gadow; P. Göttlicher; C. Günter; B. Hermberg; S. Karstensen; F. Krivan; A. I. Lucaci-Timoce; S. Lu; B. Lutz; S. Morozov; V. Morgunov; M. Reinecke; F. Sefkow; P. Smirnov; M. Terwort; A. Vargas-Trevino; N. Feege; E. Garutti; I. Marchesini; M. Ramilli; P. Eckert; T. Harion; A. Kaplan; H. Ch Schultz-Coulon; W. Shen; R. Stamen; B. Bilki; E. Norbeck; Y. Onel; G. W. Wilson; K. Kawagoe; P. D. Dauncey; A. M. Magnan; V. Bartsch; M. Wing; F. Salvatore; E. Calvo Alamillo; M. C. Fouz; J. Puerta-Pelayo; B. Bobchenko; M. Chadeeva; M. Danilov; A. Epifantsev; O. Markin; R. Mizuk; E. Novikov; V. Popov; V. Rusinov; E. Tarkovsky; N. Kirikova; V. Kozlov; P. Smirnov; Y. Soloviev; P. Buzhan; A. Ilyin; V. Kantserov; V. Kaplin; A. Karakash; E. Popova; V. Tikhomirov; C. Kiesling; K. Seidel; F. Simon; C. Soldner; M. Szalay; M. Tesar; L. Weuste; M. S. Amjad; J. Bonis; S. Callier; S. Conforti Di Lorenzo; P. Cornebise; Ph Doublet; F. Dulucq; J. Fleury; T. Frisson; N. Van Der Kolk; H. Li; G. Martin-Chassard; F. Richard; Ch De La Taille; R. Pöschl; L. Raux; J. Rouëné; N. Seguin-Moreau; M. Anduze; V. Boudry; J. C. Brient; D. Jeans; P. Mora De Freitas; G. Musat; M. Reinhard; M. Ruan; H. Videau; B. Bulanek; J. Zacek; J. Cvach; P. Gallus; M. Havranek; M. Janata; J. Kvasnicka; D. Lednicky; M. Marcisovsky; I. Polak; J. Popule; L. Tomasek; M. Tomasek; P. Ruzicka; P. Sicho; J. Smolik; V. Vrba; J. Zalesak; B. Belhorma; H. Ghazlane; T. Takeshita; S. Uozumi; M. Götze; O. Hartbrich; J. Sauer; S. Weber; C. Zeitnitz

doi:10.1088/1748-0221/8/07/P07005

Validation of GEANT4 Monte Carlo models with a highly granular scintillator-steel hadron calorimeter

C. Adloff
, J. Blaha
, J. J. Blaising
, C. Drancourt
, A. Espargilière
, R. Gaglione
, N. Geffroy
, Y. Karyotakis
, J. Prast
, G. Vouters
, K. Francis
, J. Repond
, J. Schlereth
, J. Smith
, L. Xia
, E. Baldolemar
, J. Li
, S. T. Park
, M. Sosebee
, A. P. White

J. Yu, T. Buanes, G. Eigen, Y. Mikami, N. K. Watson, G. Mavromanolakis, M. A. Thomson, D. R. Ward, W. Yan, D. Benchekroun, A. Hoummada, Y. Khoulaki, J. Apostolakis, A. Dotti, G. Folger, V. Ivantchenko, V. Uzhinskiy, M. Benyamna, C. Cârloganu, F. Fehr, P. Gay, S. Manen, L. Royer, G. C. Blazey, A. Dyshkant, J. G.R. Lima, V. Zutshi, J. Y. Hostachy, L. Morin, U. Cornett, D. David, G. Falley, K. Gadow, P. Göttlicher, C. Günter, B. Hermberg, S. Karstensen, F. Krivan, A. I. Lucaci-Timoce, S. Lu, B. Lutz, S. Morozov, V. Morgunov, M. Reinecke, F. Sefkow, P. Smirnov, M. Terwort, A. Vargas-Trevino, N. Feege, E. Garutti, I. Marchesini, M. Ramilli, P. Eckert, T. Harion, A. Kaplan, H. Ch Schultz-Coulon, W. Shen, R. Stamen, B. Bilki, E. Norbeck, Y. Onel, G. W. Wilson, K. Kawagoe, P. D. Dauncey, A. M. Magnan, V. Bartsch, M. Wing, F. Salvatore, E. Calvo Alamillo, M. C. Fouz, J. Puerta-Pelayo, B. Bobchenko, M. Chadeeva, M. Danilov, A. Epifantsev, O. Markin, R. Mizuk, E. Novikov, V. Popov, V. Rusinov, E. Tarkovsky, N. Kirikova, V. Kozlov, P. Smirnov, Y. Soloviev, P. Buzhan, A. Ilyin, V. Kantserov, V. Kaplin, A. Karakash, E. Popova, V. Tikhomirov, C. Kiesling, K. Seidel, F. Simon, C. Soldner, M. Szalay, M. Tesar, L. Weuste, M. S. Amjad, J. Bonis, S. Callier, S. Conforti Di Lorenzo, P. Cornebise, Ph Doublet, F. Dulucq, J. Fleury, T. Frisson, N. Van Der Kolk, H. Li, G. Martin-Chassard, F. Richard, Ch De La Taille, R. Pöschl, L. Raux, J. Rouëné, N. Seguin-Moreau, M. Anduze, V. Boudry, J. C. Brient, D. Jeans, P. Mora De Freitas, G. Musat, M. Reinhard, M. Ruan, H. Videau, B. Bulanek, J. Zacek, J. Cvach, P. Gallus, M. Havranek, M. Janata, J. Kvasnicka, D. Lednicky, M. Marcisovsky, I. Polak, J. Popule, L. Tomasek, M. Tomasek, P. Ruzicka, P. Sicho, J. Smolik, V. Vrba, J. Zalesak, B. Belhorma, H. Ghazlane, T. Takeshita, S. Uozumi, M. Götze, O. Hartbrich, J. Sauer, S. Weber, C. Zeitnitz

Laboratoire de Physique des Particules
Argonne National Laboratory
University of Texas at Arlington
University of Bergen
University of Birmingham
University of Cambridge
European Organization for Nuclear Research
University of Science and Technology of China
Université Hassan II Aïn Chock - Casablanca et LASAARE
Clermont-Auvergne University
Northern Illinois University
Laboratoire de Physique Subatomique et de Cosmologie de Grenoble
c/o DESY
ITEP
Universität Hamburg
University of Heidelberg
University of Iowa
University of Kansas
Kyushu University
Imperial College London
University College London
University of Sussex
Royal Holloway University of London
Centro de Investigaciones Energéticas Medioambientales y Tecnológicas (CIEMAT)
Institute for Theoretical and Experimental Physics
Moscow Institute of Physics and Technology
P.N. Lebedev Physical Institute of the Russian Academy of Sciences
National Research Nuclear University MEPhI
Max-Planck-Institut für Physik
Université Paris-Sud
LPSC Grenoble
Ip Paris
Charles University
Institute of Physics of the Czech Academy of Sciences
Centre National de l'Energie des Sciences Techniques Nucleaires
Shinshu University
Bergische Universität Gesamthochschule Wuppertal

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

Calorimeters with a high granularity are a fundamental requirement of the Particle Flow paradigm. This paper focuses on the prototype of a hadron calorimeter with analog readout, consisting of thirty-eight scintillator layers alternating with steel absorber planes. The scintillator plates are finely segmented into tiles individually read out via Silicon Photomultipliers. The presented results are based on data collected with pion beams in the energy range from 8 GeV to 100 GeV. The fine segmentation of the sensitive layers and the high sampling frequency allow for an excellent reconstruction of the spatial development of hadronic showers. A comparison between data and Monte Carlo simulations is presented, concerning both the longitudinal and lateral development of hadronic showers and the global response of the calorimeter. The performance of several GEANT4 physics lists with respect to these observables is evaluated.

langue originale	Anglais
Numéro d'article	P07005
journal	Journal of Instrumentation
Volume	8
Numéro de publication	7
Les DOIs	https://doi.org/10.1088/1748-0221/8/07/P07005
état	Publié - 1 janv. 2013

Accès au document

10.1088/1748-0221/8/07/P07005

Contient cette citation

Adloff, C., Blaha, J., Blaising, J. J., Drancourt, C., Espargilière, A., Gaglione, R., Geffroy, N., Karyotakis, Y., Prast, J., Vouters, G., Francis, K., Repond, J., Schlereth, J., Smith, J., Xia, L., Baldolemar, E., Li, J., Park, S. T., Sosebee, M., ... Zeitnitz, C. (2013). Validation of GEANT4 Monte Carlo models with a highly granular scintillator-steel hadron calorimeter. Journal of Instrumentation, 8(7), Article P07005. https://doi.org/10.1088/1748-0221/8/07/P07005

@article{727793474b3a4843ba28b607c7da7264,

title = "Validation of GEANT4 Monte Carlo models with a highly granular scintillator-steel hadron calorimeter",

abstract = "Calorimeters with a high granularity are a fundamental requirement of the Particle Flow paradigm. This paper focuses on the prototype of a hadron calorimeter with analog readout, consisting of thirty-eight scintillator layers alternating with steel absorber planes. The scintillator plates are finely segmented into tiles individually read out via Silicon Photomultipliers. The presented results are based on data collected with pion beams in the energy range from 8 GeV to 100 GeV. The fine segmentation of the sensitive layers and the high sampling frequency allow for an excellent reconstruction of the spatial development of hadronic showers. A comparison between data and Monte Carlo simulations is presented, concerning both the longitudinal and lateral development of hadronic showers and the global response of the calorimeter. The performance of several GEANT4 physics lists with respect to these observables is evaluated.",

keywords = "Calorimeter methods, Detector modelling and simulations I (interaction of radiation with matter, interaction of photons with matter, interaction of hadrons with matter, etc), Interaction of radiation with matter",

author = "C. Adloff and J. Blaha and Blaising, \{J. J.\} and C. Drancourt and A. Espargili{\`e}re and R. Gaglione and N. Geffroy and Y. Karyotakis and J. Prast and G. Vouters and K. Francis and J. Repond and J. Schlereth and J. Smith and L. Xia and E. Baldolemar and J. Li and Park, \{S. T.\} and M. Sosebee and White, \{A. P.\} and J. Yu and T. Buanes and G. Eigen and Y. Mikami and Watson, \{N. K.\} and G. Mavromanolakis and Thomson, \{M. A.\} and Ward, \{D. R.\} and W. Yan and D. Benchekroun and A. Hoummada and Y. Khoulaki and J. Apostolakis and A. Dotti and G. Folger and V. Ivantchenko and V. Uzhinskiy and M. Benyamna and C. C{\^a}rloganu and F. Fehr and P. Gay and S. Manen and L. Royer and Blazey, \{G. C.\} and A. Dyshkant and Lima, \{J. G.R.\} and V. Zutshi and Hostachy, \{J. Y.\} and L. Morin and U. Cornett and D. David and G. Falley and K. Gadow and P. G{\"o}ttlicher and C. G{\"u}nter and B. Hermberg and S. Karstensen and F. Krivan and Lucaci-Timoce, \{A. I.\} and S. Lu and B. Lutz and S. Morozov and V. Morgunov and M. Reinecke and F. Sefkow and P. Smirnov and M. Terwort and A. Vargas-Trevino and N. Feege and E. Garutti and I. Marchesini and M. Ramilli and P. Eckert and T. Harion and A. Kaplan and Schultz-Coulon, \{H. Ch\} and W. Shen and R. Stamen and B. Bilki and E. Norbeck and Y. Onel and Wilson, \{G. W.\} and K. Kawagoe and Dauncey, \{P. D.\} and Magnan, \{A. M.\} and V. Bartsch and M. Wing and F. Salvatore and \{Calvo Alamillo\}, E. and Fouz, \{M. C.\} and J. Puerta-Pelayo and B. Bobchenko and M. Chadeeva and M. Danilov and A. Epifantsev and O. Markin and R. Mizuk and E. Novikov and V. Popov and V. Rusinov and E. Tarkovsky and N. Kirikova and V. Kozlov and P. Smirnov and Y. Soloviev and P. Buzhan and A. Ilyin and V. Kantserov and V. Kaplin and A. Karakash and E. Popova and V. Tikhomirov and C. Kiesling and K. Seidel and F. Simon and C. Soldner and M. Szalay and M. Tesar and L. Weuste and Amjad, \{M. S.\} and J. Bonis and S. Callier and \{Conforti Di Lorenzo\}, S. and P. Cornebise and Ph Doublet and F. Dulucq and J. Fleury and T. Frisson and \{Van Der Kolk\}, N. and H. Li and G. Martin-Chassard and F. Richard and \{De La Taille\}, Ch and R. P{\"o}schl and L. Raux and J. Rou{\"e}n{\'e} and N. Seguin-Moreau and M. Anduze and V. Boudry and Brient, \{J. C.\} and D. Jeans and \{Mora De Freitas\}, P. and G. Musat and M. Reinhard and M. Ruan and H. Videau and B. Bulanek and J. Zacek and J. Cvach and P. Gallus and M. Havranek and M. Janata and J. Kvasnicka and D. Lednicky and M. Marcisovsky and I. Polak and J. Popule and L. Tomasek and M. Tomasek and P. Ruzicka and P. Sicho and J. Smolik and V. Vrba and J. Zalesak and B. Belhorma and H. Ghazlane and T. Takeshita and S. Uozumi and M. G{\"o}tze and O. Hartbrich and J. Sauer and S. Weber and C. Zeitnitz",

year = "2013",

month = jan,

day = "1",

doi = "10.1088/1748-0221/8/07/P07005",

language = "English",

volume = "8",

journal = "Journal of Instrumentation",

issn = "1748-0221",

number = "7",

}

Adloff, C, Blaha, J, Blaising, JJ, Drancourt, C, Espargilière, A, Gaglione, R, Geffroy, N, Karyotakis, Y, Prast, J, Vouters, G, Francis, K, Repond, J, Schlereth, J, Smith, J, Xia, L, Baldolemar, E, Li, J, Park, ST, Sosebee, M, White, AP, Yu, J, Buanes, T, Eigen, G, Mikami, Y, Watson, NK, Mavromanolakis, G, Thomson, MA, Ward, DR, Yan, W, Benchekroun, D, Hoummada, A, Khoulaki, Y, Apostolakis, J, Dotti, A, Folger, G, Ivantchenko, V, Uzhinskiy, V, Benyamna, M, Cârloganu, C, Fehr, F, Gay, P, Manen, S, Royer, L, Blazey, GC, Dyshkant, A, Lima, JGR, Zutshi, V, Hostachy, JY, Morin, L, Cornett, U, David, D, Falley, G, Gadow, K, Göttlicher, P, Günter, C, Hermberg, B, Karstensen, S, Krivan, F, Lucaci-Timoce, AI, Lu, S, Lutz, B, Morozov, S, Morgunov, V, Reinecke, M, Sefkow, F, Smirnov, P, Terwort, M, Vargas-Trevino, A, Feege, N, Garutti, E, Marchesini, I, Ramilli, M, Eckert, P, Harion, T, Kaplan, A, Schultz-Coulon, HC, Shen, W, Stamen, R, Bilki, B, Norbeck, E, Onel, Y, Wilson, GW, Kawagoe, K, Dauncey, PD, Magnan, AM, Bartsch, V, Wing, M, Salvatore, F, Calvo Alamillo, E, Fouz, MC, Puerta-Pelayo, J, Bobchenko, B, Chadeeva, M, Danilov, M, Epifantsev, A, Markin, O, Mizuk, R, Novikov, E, Popov, V, Rusinov, V, Tarkovsky, E, Kirikova, N, Kozlov, V, Smirnov, P, Soloviev, Y, Buzhan, P, Ilyin, A, Kantserov, V, Kaplin, V, Karakash, A, Popova, E, Tikhomirov, V, Kiesling, C, Seidel, K, Simon, F, Soldner, C, Szalay, M, Tesar, M, Weuste, L, Amjad, MS, Bonis, J, Callier, S, Conforti Di Lorenzo, S, Cornebise, P, Doublet, P, Dulucq, F, Fleury, J, Frisson, T, Van Der Kolk, N, Li, H, Martin-Chassard, G, Richard, F, De La Taille, C, Pöschl, R, Raux, L, Rouëné, J, Seguin-Moreau, N, Anduze, M, Boudry, V, Brient, JC, Jeans, D, Mora De Freitas, P, Musat, G, Reinhard, M, Ruan, M, Videau, H, Bulanek, B, Zacek, J, Cvach, J, Gallus, P, Havranek, M, Janata, M, Kvasnicka, J, Lednicky, D, Marcisovsky, M, Polak, I, Popule, J, Tomasek, L, Tomasek, M, Ruzicka, P, Sicho, P, Smolik, J, Vrba, V, Zalesak, J, Belhorma, B, Ghazlane, H, Takeshita, T, Uozumi, S, Götze, M, Hartbrich, O, Sauer, J, Weber, S & Zeitnitz, C 2013, 'Validation of GEANT4 Monte Carlo models with a highly granular scintillator-steel hadron calorimeter', Journal of Instrumentation, VOL. 8, Numéro 7, P07005. https://doi.org/10.1088/1748-0221/8/07/P07005

TY - JOUR

T1 - Validation of GEANT4 Monte Carlo models with a highly granular scintillator-steel hadron calorimeter

AU - Adloff, C.

AU - Blaha, J.

AU - Blaising, J. J.

AU - Drancourt, C.

AU - Espargilière, A.

AU - Gaglione, R.

AU - Geffroy, N.

AU - Karyotakis, Y.

AU - Prast, J.

AU - Vouters, G.

AU - Francis, K.

AU - Repond, J.

AU - Schlereth, J.

AU - Smith, J.

AU - Xia, L.

AU - Baldolemar, E.

AU - Li, J.

AU - Park, S. T.

AU - Sosebee, M.

AU - White, A. P.

AU - Yu, J.

AU - Buanes, T.

AU - Eigen, G.

AU - Mikami, Y.

AU - Watson, N. K.

AU - Mavromanolakis, G.

AU - Thomson, M. A.

AU - Ward, D. R.

AU - Yan, W.

AU - Benchekroun, D.

AU - Hoummada, A.

AU - Khoulaki, Y.

AU - Apostolakis, J.

AU - Dotti, A.

AU - Folger, G.

AU - Ivantchenko, V.

AU - Uzhinskiy, V.

AU - Benyamna, M.

AU - Cârloganu, C.

AU - Fehr, F.

AU - Gay, P.

AU - Manen, S.

AU - Royer, L.

AU - Blazey, G. C.

AU - Dyshkant, A.

AU - Lima, J. G.R.

AU - Zutshi, V.

AU - Hostachy, J. Y.

AU - Morin, L.

AU - Cornett, U.

AU - David, D.

AU - Falley, G.

AU - Gadow, K.

AU - Göttlicher, P.

AU - Günter, C.

AU - Hermberg, B.

AU - Karstensen, S.

AU - Krivan, F.

AU - Lucaci-Timoce, A. I.

AU - Lu, S.

AU - Lutz, B.

AU - Morozov, S.

AU - Morgunov, V.

AU - Reinecke, M.

AU - Sefkow, F.

AU - Smirnov, P.

AU - Terwort, M.

AU - Vargas-Trevino, A.

AU - Feege, N.

AU - Garutti, E.

AU - Marchesini, I.

AU - Ramilli, M.

AU - Eckert, P.

AU - Harion, T.

AU - Kaplan, A.

AU - Schultz-Coulon, H. Ch

AU - Shen, W.

AU - Stamen, R.

AU - Bilki, B.

AU - Norbeck, E.

AU - Onel, Y.

AU - Wilson, G. W.

AU - Kawagoe, K.

AU - Dauncey, P. D.

AU - Magnan, A. M.

AU - Bartsch, V.

AU - Wing, M.

AU - Salvatore, F.

AU - Calvo Alamillo, E.

AU - Fouz, M. C.

AU - Puerta-Pelayo, J.

AU - Bobchenko, B.

AU - Chadeeva, M.

AU - Danilov, M.

AU - Epifantsev, A.

AU - Markin, O.

AU - Mizuk, R.

AU - Novikov, E.

AU - Popov, V.

AU - Rusinov, V.

AU - Tarkovsky, E.

AU - Kirikova, N.

AU - Kozlov, V.

AU - Smirnov, P.

AU - Soloviev, Y.

AU - Buzhan, P.

AU - Ilyin, A.

AU - Kantserov, V.

AU - Kaplin, V.

AU - Karakash, A.

AU - Popova, E.

AU - Tikhomirov, V.

AU - Kiesling, C.

AU - Seidel, K.

AU - Simon, F.

AU - Soldner, C.

AU - Szalay, M.

AU - Tesar, M.

AU - Weuste, L.

AU - Amjad, M. S.

AU - Bonis, J.

AU - Callier, S.

AU - Conforti Di Lorenzo, S.

AU - Cornebise, P.

AU - Doublet, Ph

AU - Dulucq, F.

AU - Fleury, J.

AU - Frisson, T.

AU - Van Der Kolk, N.

AU - Li, H.

AU - Martin-Chassard, G.

AU - Richard, F.

AU - De La Taille, Ch

AU - Pöschl, R.

AU - Raux, L.

AU - Rouëné, J.

AU - Seguin-Moreau, N.

AU - Anduze, M.

AU - Boudry, V.

AU - Brient, J. C.

AU - Jeans, D.

AU - Mora De Freitas, P.

AU - Musat, G.

AU - Reinhard, M.

AU - Ruan, M.

AU - Videau, H.

AU - Bulanek, B.

AU - Zacek, J.

AU - Cvach, J.

AU - Gallus, P.

AU - Havranek, M.

AU - Janata, M.

AU - Kvasnicka, J.

AU - Lednicky, D.

AU - Marcisovsky, M.

AU - Polak, I.

AU - Popule, J.

AU - Tomasek, L.

AU - Tomasek, M.

AU - Ruzicka, P.

AU - Sicho, P.

AU - Smolik, J.

AU - Vrba, V.

AU - Zalesak, J.

AU - Belhorma, B.

AU - Ghazlane, H.

AU - Takeshita, T.

AU - Uozumi, S.

AU - Götze, M.

AU - Hartbrich, O.

AU - Sauer, J.

AU - Weber, S.

AU - Zeitnitz, C.

PY - 2013/1/1

Y1 - 2013/1/1

N2 - Calorimeters with a high granularity are a fundamental requirement of the Particle Flow paradigm. This paper focuses on the prototype of a hadron calorimeter with analog readout, consisting of thirty-eight scintillator layers alternating with steel absorber planes. The scintillator plates are finely segmented into tiles individually read out via Silicon Photomultipliers. The presented results are based on data collected with pion beams in the energy range from 8 GeV to 100 GeV. The fine segmentation of the sensitive layers and the high sampling frequency allow for an excellent reconstruction of the spatial development of hadronic showers. A comparison between data and Monte Carlo simulations is presented, concerning both the longitudinal and lateral development of hadronic showers and the global response of the calorimeter. The performance of several GEANT4 physics lists with respect to these observables is evaluated.

AB - Calorimeters with a high granularity are a fundamental requirement of the Particle Flow paradigm. This paper focuses on the prototype of a hadron calorimeter with analog readout, consisting of thirty-eight scintillator layers alternating with steel absorber planes. The scintillator plates are finely segmented into tiles individually read out via Silicon Photomultipliers. The presented results are based on data collected with pion beams in the energy range from 8 GeV to 100 GeV. The fine segmentation of the sensitive layers and the high sampling frequency allow for an excellent reconstruction of the spatial development of hadronic showers. A comparison between data and Monte Carlo simulations is presented, concerning both the longitudinal and lateral development of hadronic showers and the global response of the calorimeter. The performance of several GEANT4 physics lists with respect to these observables is evaluated.

KW - Calorimeter methods

KW - Detector modelling and simulations I (interaction of radiation with matter, interaction of photons with matter, interaction of hadrons with matter, etc)

KW - Interaction of radiation with matter

U2 - 10.1088/1748-0221/8/07/P07005

DO - 10.1088/1748-0221/8/07/P07005

M3 - Article

AN - SCOPUS:84881262526

SN - 1748-0221

VL - 8

JO - Journal of Instrumentation

JF - Journal of Instrumentation

IS - 7

M1 - P07005

ER -

Validation of GEANT4 Monte Carlo models with a highly granular scintillator-steel hadron calorimeter

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