The MUSE beamline calorimeter

W. Lin; T. Rostomyan; R. Gilman; S. Strauch; C. Meier; C. Nestler; M. Ali; H. Atac; J. C. Bernauer; W. J. Briscoe; A. Christopher Ndukwe; E. W. Cline; K. Deiters; S. Dogra; E. J. Downie; Z. Duan; I. P. Fernando; A. Flannery; D. Ghosal; A. Golossanov; J. Guo; N. S. Ifat; Y. Ilieva; M. Kohl; I. Lavrukhin; L. Li; W. Lorenzon; P. Mohanmurthy; S. J. Nazeer; M. Nicol; T. Patel; A. Prosnyakov; R. D. Ransome; R. Ratvasky; H. Reid; P. E. Reimer; R. Richards; G. Ron; O. M. Ruimi; K. Salamone; N. Sparveris; N. Wuerfel; D. A. Yaari

doi:10.1016/j.nima.2025.170754

The MUSE beamline calorimeter

W. Lin
, T. Rostomyan
, R. Gilman
, S. Strauch
, C. Meier
, C. Nestler
, M. Ali
, H. Atac
, J. C. Bernauer
, W. J. Briscoe
, A. Christopher Ndukwe
, E. W. Cline
, K. Deiters
, S. Dogra
, E. J. Downie
, Z. Duan
, I. P. Fernando
, A. Flannery
, D. Ghosal
, A. Golossanov

J. Guo, N. S. Ifat, Y. Ilieva, M. Kohl, I. Lavrukhin, L. Li, W. Lorenzon, P. Mohanmurthy, S. J. Nazeer, M. Nicol, T. Patel, A. Prosnyakov, R. D. Ransome, R. Ratvasky, H. Reid, P. E. Reimer, R. Richards, G. Ron, O. M. Ruimi, K. Salamone, N. Sparveris, N. Wuerfel, D. A. Yaari

Physics and Astronomy

Stony Brook University

Rutgers - The State University of New Jersey, New Brunswick
Paul Scherrer Institute
University of South Carolina
University of Basel
Swiss Federal Institute of Technology Zurich
New Mexico State University
Temple University
George Washington University
Hampton University
Stony Brook University
Massachusetts Institute of Technology
University of Michigan, Ann Arbor
The University of Chicago
Hebrew University of Jerusalem
Argonne National Laboratory
Johannes Gutenberg University Mainz
GSI Helmholtz Centre for Heavy Ion Research

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

Abstract

The MUon Scattering Experiment (MUSE) was motivated by the proton radius puzzle arising from the discrepancy between muonic hydrogen spectroscopy and electron–proton measurements. The MUSE physics goals also include testing lepton universality, precisely measuring two-photon exchange contribution, and testing radiative corrections. MUSE addresses these physics goals through simultaneous measurement of high precision cross sections for electron–proton and muon–proton scattering using a mixed-species beam. The experiment will run at both positive and negative beam polarities. Measuring precise cross sections requires understanding both the incident beam energy and the radiative corrections. For this purpose, a lead-glass calorimeter was installed at the end of the beam line in the MUSE detector system. In this article we discuss the detector specifications, calibration and performance. We demonstrate that the detector performance is well reproduced by simulation, and meets experimental requirements.

Original language	English
Article number	170754
Journal	Nuclear Inst. and Methods in Physics Research, A
Volume	1080
DOIs	https://doi.org/10.1016/j.nima.2025.170754
State	Published - Nov 2025

Keywords

Calorimeter
Elastic scattering
MUSE
Nuclear charge distribution
Proton radius

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10.1016/j.nima.2025.170754

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Lin, W., Rostomyan, T., Gilman, R., Strauch, S., Meier, C., Nestler, C., Ali, M., Atac, H., Bernauer, J. C., Briscoe, W. J., Ndukwe, A. C., Cline, E. W., Deiters, K., Dogra, S., Downie, E. J., Duan, Z., Fernando, I. P., Flannery, A., Ghosal, D., ... Yaari, D. A. (2025). The MUSE beamline calorimeter. Nuclear Inst. and Methods in Physics Research, A, 1080, Article 170754. https://doi.org/10.1016/j.nima.2025.170754

@article{eb86000c460a42f0b6a5b553e1015465,

title = "The MUSE beamline calorimeter",

abstract = "The MUon Scattering Experiment (MUSE) was motivated by the proton radius puzzle arising from the discrepancy between muonic hydrogen spectroscopy and electron–proton measurements. The MUSE physics goals also include testing lepton universality, precisely measuring two-photon exchange contribution, and testing radiative corrections. MUSE addresses these physics goals through simultaneous measurement of high precision cross sections for electron–proton and muon–proton scattering using a mixed-species beam. The experiment will run at both positive and negative beam polarities. Measuring precise cross sections requires understanding both the incident beam energy and the radiative corrections. For this purpose, a lead-glass calorimeter was installed at the end of the beam line in the MUSE detector system. In this article we discuss the detector specifications, calibration and performance. We demonstrate that the detector performance is well reproduced by simulation, and meets experimental requirements.",

keywords = "Calorimeter, Elastic scattering, MUSE, Nuclear charge distribution, Proton radius",

author = "W. Lin and T. Rostomyan and R. Gilman and S. Strauch and C. Meier and C. Nestler and M. Ali and H. Atac and Bernauer, \{J. C.\} and Briscoe, \{W. J.\} and Ndukwe, \{A. Christopher\} and Cline, \{E. W.\} and K. Deiters and S. Dogra and Downie, \{E. J.\} and Z. Duan and Fernando, \{I. P.\} and A. Flannery and D. Ghosal and A. Golossanov and J. Guo and Ifat, \{N. S.\} and Y. Ilieva and M. Kohl and I. Lavrukhin and L. Li and W. Lorenzon and P. Mohanmurthy and Nazeer, \{S. J.\} and M. Nicol and T. Patel and A. Prosnyakov and Ransome, \{R. D.\} and R. Ratvasky and H. Reid and Reimer, \{P. E.\} and R. Richards and G. Ron and Ruimi, \{O. M.\} and K. Salamone and N. Sparveris and N. Wuerfel and Yaari, \{D. A.\}",

note = "Publisher Copyright: {\textcopyright} 2025",

year = "2025",

month = nov,

doi = "10.1016/j.nima.2025.170754",

language = "English",

volume = "1080",

journal = "Nuclear Inst. and Methods in Physics Research, A",

issn = "0168-9002",

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Lin, W, Rostomyan, T, Gilman, R, Strauch, S, Meier, C, Nestler, C, Ali, M, Atac, H, Bernauer, JC, Briscoe, WJ, Ndukwe, AC, Cline, EW, Deiters, K, Dogra, S, Downie, EJ, Duan, Z, Fernando, IP, Flannery, A, Ghosal, D, Golossanov, A, Guo, J, Ifat, NS, Ilieva, Y, Kohl, M, Lavrukhin, I, Li, L, Lorenzon, W, Mohanmurthy, P, Nazeer, SJ, Nicol, M, Patel, T, Prosnyakov, A, Ransome, RD, Ratvasky, R, Reid, H, Reimer, PE, Richards, R, Ron, G, Ruimi, OM, Salamone, K, Sparveris, N, Wuerfel, N & Yaari, DA 2025, 'The MUSE beamline calorimeter', Nuclear Inst. and Methods in Physics Research, A, vol. 1080, 170754. https://doi.org/10.1016/j.nima.2025.170754

TY - JOUR

T1 - The MUSE beamline calorimeter

AU - Lin, W.

AU - Rostomyan, T.

AU - Gilman, R.

AU - Strauch, S.

AU - Meier, C.

AU - Nestler, C.

AU - Ali, M.

AU - Atac, H.

AU - Bernauer, J. C.

AU - Briscoe, W. J.

AU - Ndukwe, A. Christopher

AU - Cline, E. W.

AU - Deiters, K.

AU - Dogra, S.

AU - Downie, E. J.

AU - Duan, Z.

AU - Fernando, I. P.

AU - Flannery, A.

AU - Ghosal, D.

AU - Golossanov, A.

AU - Guo, J.

AU - Ifat, N. S.

AU - Ilieva, Y.

AU - Kohl, M.

AU - Lavrukhin, I.

AU - Li, L.

AU - Lorenzon, W.

AU - Mohanmurthy, P.

AU - Nazeer, S. J.

AU - Nicol, M.

AU - Patel, T.

AU - Prosnyakov, A.

AU - Ransome, R. D.

AU - Ratvasky, R.

AU - Reid, H.

AU - Reimer, P. E.

AU - Richards, R.

AU - Ron, G.

AU - Ruimi, O. M.

AU - Salamone, K.

AU - Sparveris, N.

AU - Wuerfel, N.

AU - Yaari, D. A.

PY - 2025/11

Y1 - 2025/11

N2 - The MUon Scattering Experiment (MUSE) was motivated by the proton radius puzzle arising from the discrepancy between muonic hydrogen spectroscopy and electron–proton measurements. The MUSE physics goals also include testing lepton universality, precisely measuring two-photon exchange contribution, and testing radiative corrections. MUSE addresses these physics goals through simultaneous measurement of high precision cross sections for electron–proton and muon–proton scattering using a mixed-species beam. The experiment will run at both positive and negative beam polarities. Measuring precise cross sections requires understanding both the incident beam energy and the radiative corrections. For this purpose, a lead-glass calorimeter was installed at the end of the beam line in the MUSE detector system. In this article we discuss the detector specifications, calibration and performance. We demonstrate that the detector performance is well reproduced by simulation, and meets experimental requirements.

AB - The MUon Scattering Experiment (MUSE) was motivated by the proton radius puzzle arising from the discrepancy between muonic hydrogen spectroscopy and electron–proton measurements. The MUSE physics goals also include testing lepton universality, precisely measuring two-photon exchange contribution, and testing radiative corrections. MUSE addresses these physics goals through simultaneous measurement of high precision cross sections for electron–proton and muon–proton scattering using a mixed-species beam. The experiment will run at both positive and negative beam polarities. Measuring precise cross sections requires understanding both the incident beam energy and the radiative corrections. For this purpose, a lead-glass calorimeter was installed at the end of the beam line in the MUSE detector system. In this article we discuss the detector specifications, calibration and performance. We demonstrate that the detector performance is well reproduced by simulation, and meets experimental requirements.

KW - Calorimeter

KW - Elastic scattering

KW - MUSE

KW - Nuclear charge distribution

KW - Proton radius

UR - https://www.scopus.com/pages/publications/105009455105

U2 - 10.1016/j.nima.2025.170754

DO - 10.1016/j.nima.2025.170754

M3 - Article

SN - 0168-9002

VL - 1080

JO - Nuclear Inst. and Methods in Physics Research, A

JF - Nuclear Inst. and Methods in Physics Research, A

M1 - 170754

ER -

The MUSE beamline calorimeter

Abstract

Keywords

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