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Main Authors: Angelino, Emanuele, Beligotti, Veronica, Bellagamba, Lorenzo, Bonali, Elena, Bruni, Graziano, Di Gangi, Pietro, Lucchetti, Gian Marco, Mancuso, Andrea, Mazza, Virginia, Sartorelli, Gabriella, Selvi, Marco, Semeria, Franco, Razeto, Alessandro, Vecchi, Stefania, Zavattini, Guido
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.02826
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author Angelino, Emanuele
Beligotti, Veronica
Bellagamba, Lorenzo
Bonali, Elena
Bruni, Graziano
Di Gangi, Pietro
Lucchetti, Gian Marco
Mancuso, Andrea
Mazza, Virginia
Sartorelli, Gabriella
Selvi, Marco
Semeria, Franco
Razeto, Alessandro
Vecchi, Stefania
Zavattini, Guido
author_facet Angelino, Emanuele
Beligotti, Veronica
Bellagamba, Lorenzo
Bonali, Elena
Bruni, Graziano
Di Gangi, Pietro
Lucchetti, Gian Marco
Mancuso, Andrea
Mazza, Virginia
Sartorelli, Gabriella
Selvi, Marco
Semeria, Franco
Razeto, Alessandro
Vecchi, Stefania
Zavattini, Guido
contents Many models exist to describe the single photoelectron response of single photon counting photomultipliers. Generally to describe the spectral region between the fully amplified primary photoelectron peak and the electronics pedestal an ad hoc function is used (often an exponentially modified gaussian) attributing this region to `noise'. In this paper, following the physical description of back-scattered primary photoelectrons at the first dynode described in the "The Photomultiplier Handbook" by A. G. Wright published by Oxford University Press, we derive an analytical function describing these partially amplified primary photoelectron at the first dynode. This function depends only on intrinsic parameters of the photomultiplier such as the gain at the first dynode and the intrinsic resolution of the dynode chain following the first. Furthermore, analytical descriptions of the fully amplified peak and very low charge signals are derived. The model has been successfully validated with data from two different photomultipliers acquired with a low-noise amplifier.
format Preprint
id arxiv_https___arxiv_org_abs_2604_02826
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Analytical model for the photomultiplier single photoelectron response including the electron back-scattering contribution
Angelino, Emanuele
Beligotti, Veronica
Bellagamba, Lorenzo
Bonali, Elena
Bruni, Graziano
Di Gangi, Pietro
Lucchetti, Gian Marco
Mancuso, Andrea
Mazza, Virginia
Sartorelli, Gabriella
Selvi, Marco
Semeria, Franco
Razeto, Alessandro
Vecchi, Stefania
Zavattini, Guido
Instrumentation and Detectors
High Energy Physics - Experiment
Many models exist to describe the single photoelectron response of single photon counting photomultipliers. Generally to describe the spectral region between the fully amplified primary photoelectron peak and the electronics pedestal an ad hoc function is used (often an exponentially modified gaussian) attributing this region to `noise'. In this paper, following the physical description of back-scattered primary photoelectrons at the first dynode described in the "The Photomultiplier Handbook" by A. G. Wright published by Oxford University Press, we derive an analytical function describing these partially amplified primary photoelectron at the first dynode. This function depends only on intrinsic parameters of the photomultiplier such as the gain at the first dynode and the intrinsic resolution of the dynode chain following the first. Furthermore, analytical descriptions of the fully amplified peak and very low charge signals are derived. The model has been successfully validated with data from two different photomultipliers acquired with a low-noise amplifier.
title Analytical model for the photomultiplier single photoelectron response including the electron back-scattering contribution
topic Instrumentation and Detectors
High Energy Physics - Experiment
url https://arxiv.org/abs/2604.02826