A photomultiplier tube model for the water Cherenkov detectors of LAGO

the LAGO Collaboration

A photomultiplier tube model for the water Cherenkov detectors of LAGO

the LAGO Collaboration

Producción científica: Contribución a una revista › Artículo de la conferencia › revisión exhaustiva

Resumen

The Latin American Giant Observatory (LAGO) is an international experiment covering 10 Latin American countries and Spain. LAGO researches gamma-ray bursts and space weather phenomena using water Cherenkov detectors (WCDs) deployed at different altitudes. Large-area (8-inches) photomultipliers sense Cherenkov radiation produced by secondary particles crossing the WCDs. We present a generic photomultiplier model applied to the Hamamatsu R5912 tube, used in most of LAGO’ WCDs. The model depends on the number of dynodes, the bias voltage, the number of incident photons, the photodetection efficiency, and the bias network. Besides, the implementation of the model includes a simulation of the front-end of LAGO’s acquisition electronics, allowing the linearity of the system to be evaluated under different conditions. The model was validated with data recorded by the MuTe-Chitaga (Bucaramanga, Colombia) and Nahuelito (Bariloche, Argentina) WCDs. Geant4 simulations estimate the number of Cherenkov photons arriving at the photomultiplier. We contrasted the anode/dynode pulse amplitude ratio between the data and the model prediction. We also compared the estimated and measured vertical equivalent muon charge (pulse area). The vertical-muon-charge estimated by the model (321.6 UADC) differs by 4% from the measured by the MuTe WCD (333 UADC).

Idioma original	Inglés
Número de artículo	281
Publicación	Proceedings of Science
Volumen	395
Estado	Publicada - 18 mar. 2022
Evento	37th International Cosmic Ray Conference, ICRC 2021 - Virtual, Berlin, Alemania Duración: 12 jul. 2021 → 23 jul. 2021

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@article{9a6112ba08314285ac0067a6541c9bf6,

title = "A photomultiplier tube model for the water Cherenkov detectors of LAGO",

abstract = "The Latin American Giant Observatory (LAGO) is an international experiment covering 10 Latin American countries and Spain. LAGO researches gamma-ray bursts and space weather phenomena using water Cherenkov detectors (WCDs) deployed at different altitudes. Large-area (8-inches) photomultipliers sense Cherenkov radiation produced by secondary particles crossing the WCDs. We present a generic photomultiplier model applied to the Hamamatsu R5912 tube, used in most of LAGO{\textquoteright} WCDs. The model depends on the number of dynodes, the bias voltage, the number of incident photons, the photodetection efficiency, and the bias network. Besides, the implementation of the model includes a simulation of the front-end of LAGO{\textquoteright}s acquisition electronics, allowing the linearity of the system to be evaluated under different conditions. The model was validated with data recorded by the MuTe-Chitaga (Bucaramanga, Colombia) and Nahuelito (Bariloche, Argentina) WCDs. Geant4 simulations estimate the number of Cherenkov photons arriving at the photomultiplier. We contrasted the anode/dynode pulse amplitude ratio between the data and the model prediction. We also compared the estimated and measured vertical equivalent muon charge (pulse area). The vertical-muon-charge estimated by the model (321.6 UADC) differs by 4% from the measured by the MuTe WCD (333 UADC).",

author = "{the LAGO Collaboration} and J. Pe{\~n}a-Rodr{\'i}guez and S. Hern{\'a}ndez-Barajas and Y. Le{\'o}n-Carre{\~n}o and N{\'u}{\~n}ez, {L. A.} and V. Agos{\'i}n and A. Alberto and C. Alvarez and J. Araya and R. Arceo and O. Areso and Arnaldi, {L. H.} and H. Asorey and M. Audelo and Ballina-Escobar, {M. G.} and Becerra-Villamizar, {D. C.} and X. Bertou and Caballero-Mora, {K. S.} and R. Caiza and R. Calder{\'o}n-Ardila and J. Calle and Fauth, {A. C.} and {Carrera Jarrin}, E. and {Castillo Delacroix}, {L. E.} and C. Castromonte and D. Cazar-Ram{\'i}rez and Diego Cogollo and {Coloma Borja}, {D. A.} and R. Conde and J. Cotzomi and D. Dallara and S. Dasso and R. Aguiar and A. Albuquerque and Reis, {J. H.A.P.} and {De Le{\'o}n}, H. and R. deLe{\'o}n-Barrios and D. Dom{\'i}nguez and M. Echiburu and M. Gonz{\'a}lez and {G{\'o}mez Berisso}, M. and {Grisales Casadiegos}, J. and Gulisano, {A. M.} and Helo, {Juan Carlos} and Condori, {C. A.H.} and Ise, {J. E.} and Nascimento, {G. K.M.} and {Leigui de Oliveira}, {M. A.} and Miletto, {F. L.} and Luzio, {V. P.} and F. Machado",

note = "Publisher Copyright: {\textcopyright} Copyright owned by the author(s).; 37th International Cosmic Ray Conference, ICRC 2021 ; Conference date: 12-07-2021 Through 23-07-2021",

year = "2022",

month = mar,

day = "18",

language = "Ingl{\'e}s",

volume = "395",

journal = "Proceedings of Science",

issn = "1824-8039",

}

TY - JOUR

T1 - A photomultiplier tube model for the water Cherenkov detectors of LAGO

AU - the LAGO Collaboration

AU - Peña-Rodríguez, J.

AU - Hernández-Barajas, S.

AU - León-Carreño, Y.

AU - Núñez, L. A.

AU - Agosín, V.

AU - Alberto, A.

AU - Alvarez, C.

AU - Araya, J.

AU - Arceo, R.

AU - Areso, O.

AU - Arnaldi, L. H.

AU - Asorey, H.

AU - Audelo, M.

AU - Ballina-Escobar, M. G.

AU - Becerra-Villamizar, D. C.

AU - Bertou, X.

AU - Caballero-Mora, K. S.

AU - Caiza, R.

AU - Calderón-Ardila, R.

AU - Calle, J.

AU - Fauth, A. C.

AU - Carrera Jarrin, E.

AU - Castillo Delacroix, L. E.

AU - Castromonte, C.

AU - Cazar-Ramírez, D.

AU - Cogollo, Diego

AU - Coloma Borja, D. A.

AU - Conde, R.

AU - Cotzomi, J.

AU - Dallara, D.

AU - Dasso, S.

AU - Aguiar, R.

AU - Albuquerque, A.

AU - Reis, J. H.A.P.

AU - De León, H.

AU - deLeón-Barrios, R.

AU - Domínguez, D.

AU - Echiburu, M.

AU - González, M.

AU - Gómez Berisso, M.

AU - Grisales Casadiegos, J.

AU - Gulisano, A. M.

AU - Helo, Juan Carlos

AU - Condori, C. A.H.

AU - Ise, J. E.

AU - Nascimento, G. K.M.

AU - Leigui de Oliveira, M. A.

AU - Miletto, F. L.

AU - Luzio, V. P.

AU - Machado, F.

PY - 2022/3/18

Y1 - 2022/3/18

N2 - The Latin American Giant Observatory (LAGO) is an international experiment covering 10 Latin American countries and Spain. LAGO researches gamma-ray bursts and space weather phenomena using water Cherenkov detectors (WCDs) deployed at different altitudes. Large-area (8-inches) photomultipliers sense Cherenkov radiation produced by secondary particles crossing the WCDs. We present a generic photomultiplier model applied to the Hamamatsu R5912 tube, used in most of LAGO’ WCDs. The model depends on the number of dynodes, the bias voltage, the number of incident photons, the photodetection efficiency, and the bias network. Besides, the implementation of the model includes a simulation of the front-end of LAGO’s acquisition electronics, allowing the linearity of the system to be evaluated under different conditions. The model was validated with data recorded by the MuTe-Chitaga (Bucaramanga, Colombia) and Nahuelito (Bariloche, Argentina) WCDs. Geant4 simulations estimate the number of Cherenkov photons arriving at the photomultiplier. We contrasted the anode/dynode pulse amplitude ratio between the data and the model prediction. We also compared the estimated and measured vertical equivalent muon charge (pulse area). The vertical-muon-charge estimated by the model (321.6 UADC) differs by 4% from the measured by the MuTe WCD (333 UADC).

AB - The Latin American Giant Observatory (LAGO) is an international experiment covering 10 Latin American countries and Spain. LAGO researches gamma-ray bursts and space weather phenomena using water Cherenkov detectors (WCDs) deployed at different altitudes. Large-area (8-inches) photomultipliers sense Cherenkov radiation produced by secondary particles crossing the WCDs. We present a generic photomultiplier model applied to the Hamamatsu R5912 tube, used in most of LAGO’ WCDs. The model depends on the number of dynodes, the bias voltage, the number of incident photons, the photodetection efficiency, and the bias network. Besides, the implementation of the model includes a simulation of the front-end of LAGO’s acquisition electronics, allowing the linearity of the system to be evaluated under different conditions. The model was validated with data recorded by the MuTe-Chitaga (Bucaramanga, Colombia) and Nahuelito (Bariloche, Argentina) WCDs. Geant4 simulations estimate the number of Cherenkov photons arriving at the photomultiplier. We contrasted the anode/dynode pulse amplitude ratio between the data and the model prediction. We also compared the estimated and measured vertical equivalent muon charge (pulse area). The vertical-muon-charge estimated by the model (321.6 UADC) differs by 4% from the measured by the MuTe WCD (333 UADC).

UR - http://www.scopus.com/inward/record.url?scp=85144110771&partnerID=8YFLogxK

M3 - Artículo de la conferencia

AN - SCOPUS:85144110771

SN - 1824-8039

VL - 395

JO - Proceedings of Science

JF - Proceedings of Science

M1 - 281

T2 - 37th International Cosmic Ray Conference, ICRC 2021

Y2 - 12 July 2021 through 23 July 2021

ER -

A photomultiplier tube model for the water Cherenkov detectors of LAGO

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