Electromagnetic energy calibration of the SoLid detector with horizontal muons

Y. Abreu; Y. Amhis; L. Arnold; G. Barber; W. Beaumont; S. Binet; I. Bolognino; M. Bongrand; J. Borg; D. Boursette; V. Buridon; B. C. Castle; H. Chanal; K. Clark; B. Coupé; P. Crochet; D. Cussans; J. D'Hondt; D. Durand; T. Durkin; M. Fallot; D. Galbinski; S. Gallego; L. Ghys; L. Giot; K. Graves; B. Guillon; S. Hayashida; D. Henaff; B. Hosseini; S. Jenzer; S. Kalcheva; L. N. Kalousis; R. Keloth; L. Koch; M. Labare; G. Lehaut; S. Manley; L. Manzanillas; J. Mermans; I. Michiels; S. Monteil; C. Moortgat; D. Newbold; V. Pestel; K. Petridis; I. Piñera; L. Popescu; A. De Roeck; N. Roy; D. Ryckbosch; N. Ryder; D. Saunders; M. H. Schune; M. Settimo; H. Rejeb Sfar; L. Simard; A. Vacheret; G. Vandierendonck; S. Van Dyck; P. Van Mulders; N. Van Remortel; S. Vercaemer; M. Verstraeten; B. Viaud; A. Weber; M. Yeresko; F. Yermia

doi:10.1088/1748-0221/20/10/P10022

Electromagnetic energy calibration of the SoLid detector with horizontal muons

Y. Abreu
, Y. Amhis
, L. Arnold
, G. Barber
, W. Beaumont
, S. Binet
, I. Bolognino
, M. Bongrand
, J. Borg
, D. Boursette
, V. Buridon
, B. C. Castle
, H. Chanal
, K. Clark
, B. Coupé
, P. Crochet
, D. Cussans
, J. D'Hondt
, D. Durand
, T. Durkin

M. Fallot, D. Galbinski, S. Gallego, L. Ghys, L. Giot, K. Graves, B. Guillon, S. Hayashida, D. Henaff, B. Hosseini, S. Jenzer, S. Kalcheva, L. N. Kalousis, R. Keloth, L. Koch, M. Labare, G. Lehaut, S. Manley, L. Manzanillas, J. Mermans, I. Michiels, S. Monteil, C. Moortgat, D. Newbold, V. Pestel, K. Petridis, I. Piñera, L. Popescu, A. De Roeck, N. Roy, D. Ryckbosch, N. Ryder, D. Saunders, M. H. Schune, M. Settimo, H. Rejeb Sfar, L. Simard, A. Vacheret, G. Vandierendonck, S. Van Dyck, P. Van Mulders, N. Van Remortel, S. Vercaemer, M. Verstraeten, B. Viaud, A. Weber, M. Yeresko, F. Yermia

Laboratory for Plasma Physics

University of Antwerp
University of Versailles Saint-Quentin-en-Yvelines
University of Bristol
Imperial College London
Université Clermont Auvergne
University of Adelaide
LPC Caen
University of Oxford
Belgian Nuclear Research Centre
Vrije Universiteit Brussel
Rutherford Appleton Laboratory
Université de Nantes
Johannes Gutenberg-Universität Mainz
King's College London
University of Ghent
CERN
Institut Universitaire de France
Fermi National Accelerator Laboratory

Research output: Contribution to journal › Article › peer-review

Abstract

SoLid is a neutrino experiment at very-short baseline searching for active-to-sterile oscillations of reactor antineutrinos. The detection principle is based on the pairing of two types of solid scintillators: polyvinyl toluene and ⁶Li:ZnS(Ag), which is a new technology used in this field of Physics. In addition to good neutron-gamma discrimination, this setup allows the detector to be highly segmented; the basic detection unit is a 5 cm cube. High segmentation provides numerous advantages including precise localisation of the Inverse Beta Decay (IBD) products, the derivation of an antineutrino energy estimator based on the isolated positron energy, and a powerful background reduction tool that relies on the topological signature of the signal. Finally, the system is read out by a network of wavelength-shifting fibres coupled to photosensors. A relative electromagnetic calibration is performed with horizontal cosmic muons. This source poses the simplest calibration problem in which a single detection unit is involved. In addition, large muon energy deposits allow us to perform a calibration at the most detailed level (i.e. per fibre) and to accurately define the fraction of energy escaping to neighbouring detection cells. A statistical precision at the sub-percent level is reached. The paper also discusses two methods to calibrate the absolute energy scale and presents their implementation and results. The first method relies on horizontal muons, though the precision is limited to around 10% because of the uncertainty in the energy distribution of such muons. A novel, alternative method based on the radioactive americium-beryllium source is proposed. It takes advantage of the electron-positron pair-production process and provides a calibration point at 3.4 MeV (i.e. in the core of the IBD positron spectrum). The paper is concluded with various cross-check including a determination of the energy spectrum of the standard cosmogenic background candle: ¹²B.

Original language	English
Article number	P10022
Journal	Journal of Instrumentation
Volume	20
Issue number	10
DOIs	https://doi.org/10.1088/1748-0221/20/10/P10022
Publication status	Published - 1 Oct 2025

Keywords

Neutrino detectors
Pattern recognition, cluster finding, calibration and fitting methods

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10.1088/1748-0221/20/10/P10022

Cite this

Abreu, Y., Amhis, Y., Arnold, L., Barber, G., Beaumont, W., Binet, S., Bolognino, I., Bongrand, M., Borg, J., Boursette, D., Buridon, V., Castle, B. C., Chanal, H., Clark, K., Coupé, B., Crochet, P., Cussans, D., D'Hondt, J., Durand, D., ... Yermia, F. (2025). Electromagnetic energy calibration of the SoLid detector with horizontal muons. Journal of Instrumentation, 20(10), Article P10022. https://doi.org/10.1088/1748-0221/20/10/P10022

@article{b3547d67fc444403b406088aaf10fe97,

title = "Electromagnetic energy calibration of the SoLid detector with horizontal muons",

abstract = "SoLid is a neutrino experiment at very-short baseline searching for active-to-sterile oscillations of reactor antineutrinos. The detection principle is based on the pairing of two types of solid scintillators: polyvinyl toluene and 6Li:ZnS(Ag), which is a new technology used in this field of Physics. In addition to good neutron-gamma discrimination, this setup allows the detector to be highly segmented; the basic detection unit is a 5 cm cube. High segmentation provides numerous advantages including precise localisation of the Inverse Beta Decay (IBD) products, the derivation of an antineutrino energy estimator based on the isolated positron energy, and a powerful background reduction tool that relies on the topological signature of the signal. Finally, the system is read out by a network of wavelength-shifting fibres coupled to photosensors. A relative electromagnetic calibration is performed with horizontal cosmic muons. This source poses the simplest calibration problem in which a single detection unit is involved. In addition, large muon energy deposits allow us to perform a calibration at the most detailed level (i.e. per fibre) and to accurately define the fraction of energy escaping to neighbouring detection cells. A statistical precision at the sub-percent level is reached. The paper also discusses two methods to calibrate the absolute energy scale and presents their implementation and results. The first method relies on horizontal muons, though the precision is limited to around 10\% because of the uncertainty in the energy distribution of such muons. A novel, alternative method based on the radioactive americium-beryllium source is proposed. It takes advantage of the electron-positron pair-production process and provides a calibration point at 3.4 MeV (i.e. in the core of the IBD positron spectrum). The paper is concluded with various cross-check including a determination of the energy spectrum of the standard cosmogenic background candle: 12B.",

keywords = "Neutrino detectors, Pattern recognition, cluster finding, calibration and fitting methods",

author = "Y. Abreu and Y. Amhis and L. Arnold and G. Barber and W. Beaumont and S. Binet and I. Bolognino and M. Bongrand and J. Borg and D. Boursette and V. Buridon and Castle, \{B. C.\} and H. Chanal and K. Clark and B. Coup{\'e} and P. Crochet and D. Cussans and J. D'Hondt and D. Durand and T. Durkin and M. Fallot and D. Galbinski and S. Gallego and L. Ghys and L. Giot and K. Graves and B. Guillon and S. Hayashida and D. Henaff and B. Hosseini and S. Jenzer and S. Kalcheva and Kalousis, \{L. N.\} and R. Keloth and L. Koch and M. Labare and G. Lehaut and S. Manley and L. Manzanillas and J. Mermans and I. Michiels and S. Monteil and C. Moortgat and D. Newbold and V. Pestel and K. Petridis and I. Pi{\~n}era and L. Popescu and \{De Roeck\}, A. and N. Roy and D. Ryckbosch and N. Ryder and D. Saunders and Schune, \{M. H.\} and M. Settimo and \{Rejeb Sfar\}, H. and L. Simard and A. Vacheret and G. Vandierendonck and \{Van Dyck\}, S. and \{Van Mulders\}, P. and \{Van Remortel\}, N. and S. Vercaemer and M. Verstraeten and B. Viaud and A. Weber and M. Yeresko and F. Yermia",

note = "Publisher Copyright: {\textcopyright} 2025 IOP Publishing Ltd and Sissa Medialab. All rights, including for text and data mining, AI training, and similar technologies, are reserved.",

year = "2025",

month = oct,

day = "1",

doi = "10.1088/1748-0221/20/10/P10022",

language = "English",

volume = "20",

journal = "Journal of Instrumentation",

issn = "1748-0221",

number = "10",

}

Abreu, Y, Amhis, Y, Arnold, L, Barber, G, Beaumont, W, Binet, S, Bolognino, I, Bongrand, M, Borg, J, Boursette, D, Buridon, V, Castle, BC, Chanal, H, Clark, K, Coupé, B, Crochet, P, Cussans, D, D'Hondt, J, Durand, D, Durkin, T, Fallot, M, Galbinski, D, Gallego, S, Ghys, L, Giot, L, Graves, K, Guillon, B, Hayashida, S, Henaff, D, Hosseini, B, Jenzer, S, Kalcheva, S, Kalousis, LN, Keloth, R, Koch, L, Labare, M, Lehaut, G, Manley, S, Manzanillas, L, Mermans, J, Michiels, I, Monteil, S, Moortgat, C, Newbold, D, Pestel, V, Petridis, K, Piñera, I, Popescu, L, De Roeck, A, Roy, N, Ryckbosch, D, Ryder, N, Saunders, D, Schune, MH, Settimo, M, Rejeb Sfar, H, Simard, L, Vacheret, A, Vandierendonck, G, Van Dyck, S, Van Mulders, P, Van Remortel, N, Vercaemer, S, Verstraeten, M, Viaud, B, Weber, A, Yeresko, M & Yermia, F 2025, 'Electromagnetic energy calibration of the SoLid detector with horizontal muons', Journal of Instrumentation, vol. 20, no. 10, P10022. https://doi.org/10.1088/1748-0221/20/10/P10022

TY - JOUR

T1 - Electromagnetic energy calibration of the SoLid detector with horizontal muons

AU - Abreu, Y.

AU - Amhis, Y.

AU - Arnold, L.

AU - Barber, G.

AU - Beaumont, W.

AU - Binet, S.

AU - Bolognino, I.

AU - Bongrand, M.

AU - Borg, J.

AU - Boursette, D.

AU - Buridon, V.

AU - Castle, B. C.

AU - Chanal, H.

AU - Clark, K.

AU - Coupé, B.

AU - Crochet, P.

AU - Cussans, D.

AU - D'Hondt, J.

AU - Durand, D.

AU - Durkin, T.

AU - Fallot, M.

AU - Galbinski, D.

AU - Gallego, S.

AU - Ghys, L.

AU - Giot, L.

AU - Graves, K.

AU - Guillon, B.

AU - Hayashida, S.

AU - Henaff, D.

AU - Hosseini, B.

AU - Jenzer, S.

AU - Kalcheva, S.

AU - Kalousis, L. N.

AU - Keloth, R.

AU - Koch, L.

AU - Labare, M.

AU - Lehaut, G.

AU - Manley, S.

AU - Manzanillas, L.

AU - Mermans, J.

AU - Michiels, I.

AU - Monteil, S.

AU - Moortgat, C.

AU - Newbold, D.

AU - Pestel, V.

AU - Petridis, K.

AU - Piñera, I.

AU - Popescu, L.

AU - De Roeck, A.

AU - Roy, N.

AU - Ryckbosch, D.

AU - Ryder, N.

AU - Saunders, D.

AU - Schune, M. H.

AU - Settimo, M.

AU - Rejeb Sfar, H.

AU - Simard, L.

AU - Vacheret, A.

AU - Vandierendonck, G.

AU - Van Dyck, S.

AU - Van Mulders, P.

AU - Van Remortel, N.

AU - Vercaemer, S.

AU - Verstraeten, M.

AU - Viaud, B.

AU - Weber, A.

AU - Yeresko, M.

AU - Yermia, F.

PY - 2025/10/1

Y1 - 2025/10/1

N2 - SoLid is a neutrino experiment at very-short baseline searching for active-to-sterile oscillations of reactor antineutrinos. The detection principle is based on the pairing of two types of solid scintillators: polyvinyl toluene and 6Li:ZnS(Ag), which is a new technology used in this field of Physics. In addition to good neutron-gamma discrimination, this setup allows the detector to be highly segmented; the basic detection unit is a 5 cm cube. High segmentation provides numerous advantages including precise localisation of the Inverse Beta Decay (IBD) products, the derivation of an antineutrino energy estimator based on the isolated positron energy, and a powerful background reduction tool that relies on the topological signature of the signal. Finally, the system is read out by a network of wavelength-shifting fibres coupled to photosensors. A relative electromagnetic calibration is performed with horizontal cosmic muons. This source poses the simplest calibration problem in which a single detection unit is involved. In addition, large muon energy deposits allow us to perform a calibration at the most detailed level (i.e. per fibre) and to accurately define the fraction of energy escaping to neighbouring detection cells. A statistical precision at the sub-percent level is reached. The paper also discusses two methods to calibrate the absolute energy scale and presents their implementation and results. The first method relies on horizontal muons, though the precision is limited to around 10% because of the uncertainty in the energy distribution of such muons. A novel, alternative method based on the radioactive americium-beryllium source is proposed. It takes advantage of the electron-positron pair-production process and provides a calibration point at 3.4 MeV (i.e. in the core of the IBD positron spectrum). The paper is concluded with various cross-check including a determination of the energy spectrum of the standard cosmogenic background candle: 12B.

AB - SoLid is a neutrino experiment at very-short baseline searching for active-to-sterile oscillations of reactor antineutrinos. The detection principle is based on the pairing of two types of solid scintillators: polyvinyl toluene and 6Li:ZnS(Ag), which is a new technology used in this field of Physics. In addition to good neutron-gamma discrimination, this setup allows the detector to be highly segmented; the basic detection unit is a 5 cm cube. High segmentation provides numerous advantages including precise localisation of the Inverse Beta Decay (IBD) products, the derivation of an antineutrino energy estimator based on the isolated positron energy, and a powerful background reduction tool that relies on the topological signature of the signal. Finally, the system is read out by a network of wavelength-shifting fibres coupled to photosensors. A relative electromagnetic calibration is performed with horizontal cosmic muons. This source poses the simplest calibration problem in which a single detection unit is involved. In addition, large muon energy deposits allow us to perform a calibration at the most detailed level (i.e. per fibre) and to accurately define the fraction of energy escaping to neighbouring detection cells. A statistical precision at the sub-percent level is reached. The paper also discusses two methods to calibrate the absolute energy scale and presents their implementation and results. The first method relies on horizontal muons, though the precision is limited to around 10% because of the uncertainty in the energy distribution of such muons. A novel, alternative method based on the radioactive americium-beryllium source is proposed. It takes advantage of the electron-positron pair-production process and provides a calibration point at 3.4 MeV (i.e. in the core of the IBD positron spectrum). The paper is concluded with various cross-check including a determination of the energy spectrum of the standard cosmogenic background candle: 12B.

KW - Neutrino detectors

KW - Pattern recognition, cluster finding, calibration and fitting methods

UR - https://www.scopus.com/pages/publications/105018853586

U2 - 10.1088/1748-0221/20/10/P10022

DO - 10.1088/1748-0221/20/10/P10022

M3 - Article

AN - SCOPUS:105018853586

SN - 1748-0221

VL - 20

JO - Journal of Instrumentation

JF - Journal of Instrumentation

IS - 10

M1 - P10022

ER -

Electromagnetic energy calibration of the SoLid detector with horizontal muons

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Keywords

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