Latest results from the RD42 collaboration on the radiation tolerance of polycrystalline diamond detectors

M. Mali; M. Artuso; L. Bäni; M. Bartosik; V. Bellini; B. Bentele; P. Bergonzo; A. Bes; J. M. Brom; G. Chiodini; D. Chren; V. Cindro; G. Claus; J. Collot; J. Cumalat; A. Dabrowski; D. Dauvergne; S. Ditalia Tchernij; G. Eigen; V. Eremin; P. Everaere; J. Forneris; L. Gallin-Martel; M. L. Gallin-Martel; K. K. Gan; M. Gastal; A. Gentry; M. Goffe; J. Goldstein; A. Golubev; A. Gorišek; E. Grigoriev; J. Grosse-Knetter; B. Hiti; D. Hits; C. Hoarau; M. Hoeferkamp; J. Hosslet; F. Hügging; C. Hutson; R. Jackman; R. Jennings-Moors; H. Kagan; K. Kanxheri; M. Kis; G. Kramberger; M. Kruger; S. Kuleshov; A. Lacoste; E. Lukosi; C. Maazouzi; I. Mandić; S. Marcatili; A. Marino; C. Mathieu; M. Menichelli; M. Mikuž; R. Molle; A. Morozzi; F. Moscatelli; J. Moss; R. Mountain; J. F. Muraz; E. A. Narazyanan; A. Oh; P. Olivero; D. Passeri; H. Pernegger; R. Perrino; F. Picollo; A. Porter; A. Portier; R. Potenza; A. Quadt; F. Rarbi; A. Re; M. Reichmann; S. Roe; O. Rossetto; P. Salter; D. A.Sanz Becerra; C. J. Schmidt; S. Schnetzer; S. Seidel; L. Servoli; R. Shivaraman; D. S. Smith; B. Sopko; V. Sopko; J. Sorenson; S. Spagnolo; S. Spanier; K. Stenson; R. Stone; B. Stugu; C. Sutera; M. Traeger; W. Trischuk; M. Truccato; C. Tuve; J. Velthuis; E. Verbitskaya; S. Wagner; R. Wallny; J. Welch; T. Wengler; M. Yamouni; J. Zalieckas; M. Zavrtanik

doi:10.1016/j.nima.2024.169202

Latest results from the RD42 collaboration on the radiation tolerance of polycrystalline diamond detectors

M. Mali, M. Artuso, L. Bäni, M. Bartosik, V. Bellini, B. Bentele, P. Bergonzo, A. Bes, J. M. Brom, G. Chiodini, D. Chren, V. Cindro, G. Claus, J. Collot, J. Cumalat, A. Dabrowski, D. Dauvergne, S. Ditalia Tchernij, G. Eigen, V. EreminP. Everaere, J. Forneris, L. Gallin-Martel, M. L. Gallin-Martel, K. K. Gan, M. Gastal, A. Gentry, M. Goffe, J. Goldstein, A. Golubev, A. Gorišek, E. Grigoriev, J. Grosse-Knetter, B. Hiti, D. Hits, C. Hoarau, M. Hoeferkamp, J. Hosslet, F. Hügging, C. Hutson, R. Jackman, R. Jennings-Moors, H. Kagan, K. Kanxheri, M. Kis, G. Kramberger, M. Kruger, S. Kuleshov, A. Lacoste, E. Lukosi, C. Maazouzi, I. Mandić, S. Marcatili, A. Marino, C. Mathieu, M. Menichelli, M. Mikuž, R. Molle, A. Morozzi, F. Moscatelli, J. Moss, R. Mountain, J. F. Muraz, E. A. Narazyanan, A. Oh, P. Olivero, D. Passeri, H. Pernegger, R. Perrino, F. Picollo, A. Porter, A. Portier, R. Potenza, A. Quadt, F. Rarbi, A. Re, M. Reichmann, S. Roe, O. Rossetto, P. Salter, D. A.Sanz Becerra, C. J. Schmidt, S. Schnetzer, S. Seidel, L. Servoli, R. Shivaraman, D. S. Smith, B. Sopko, V. Sopko, J. Sorenson, S. Spagnolo, S. Spanier, K. Stenson, R. Stone, B. Stugu, C. Sutera, M. Traeger, W. Trischuk, M. Truccato, C. Tuve, J. Velthuis, E. Verbitskaya, S. Wagner, R. Wallny, J. Welch, T. Wengler, M. Yamouni, J. Zalieckas, M. Zavrtanik

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

1 Scopus citations

Abstract

As nuclear and particle physics facilities move to higher intensities, the detectors used there must be more radiation tolerant. Diamond is in use at many facilities due to its inherent radiation tolerance and ease of use. In this article we present our radiation tolerance measurements of the highest quality polycrystalline Chemical Vapor Deposition (pCVD) diamond material for irradiations from a range of proton energies, pions and neutrons up to a fluence of 2×10¹⁶particles/cm². We have measured the damage constant as a function of energy and particle species and compared it with theoretical models. We also present measurements of the rate dependence of pulse height for non-irradiated and irradiated pCVD diamond pad and pixel detectors, including detectors tested over a range of particle fluxes up to 20 MHz/cm² with both pad and pixel readout electronics. Our test beam results indicate a 2% upper limit to the pulse height dependence of unirradiated and neutron irradiated pCVD diamond detectors leading to the conclusion that the pulse height in pCVD diamond detectors is, at most, minimally dependent on the particle flux.

Original language	English (US)
Article number	169202
Journal	Nuclear Instruments and Methods in Physics Research, Section A: Accelerators, Spectrometers, Detectors and Associated Equipment
Volume	1062
DOIs	https://doi.org/10.1016/j.nima.2024.169202
State	Published - May 2024
Externally published	Yes

All Science Journal Classification (ASJC) codes

Nuclear and High Energy Physics
Instrumentation

Keywords

3D diamond detectors
Chemical vapor deposition
Diamond detectors
Radiation tolerant detectors
pCVD diamond

Access to Document

10.1016/j.nima.2024.169202

Cite this

Mali, M., Artuso, M., Bäni, L., Bartosik, M., Bellini, V., Bentele, B., Bergonzo, P., Bes, A., Brom, J. M., Chiodini, G., Chren, D., Cindro, V., Claus, G., Collot, J., Cumalat, J., Dabrowski, A., Dauvergne, D., Tchernij, S. D., Eigen, G., ... Zavrtanik, M. (2024). Latest results from the RD42 collaboration on the radiation tolerance of polycrystalline diamond detectors. Nuclear Instruments and Methods in Physics Research, Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, 1062, Article 169202. https://doi.org/10.1016/j.nima.2024.169202

@article{ae05a5bdabce49ee94f6ae2a11054ade,

title = "Latest results from the RD42 collaboration on the radiation tolerance of polycrystalline diamond detectors",

abstract = "As nuclear and particle physics facilities move to higher intensities, the detectors used there must be more radiation tolerant. Diamond is in use at many facilities due to its inherent radiation tolerance and ease of use. In this article we present our radiation tolerance measurements of the highest quality polycrystalline Chemical Vapor Deposition (pCVD) diamond material for irradiations from a range of proton energies, pions and neutrons up to a fluence of 2×1016particles/cm2. We have measured the damage constant as a function of energy and particle species and compared it with theoretical models. We also present measurements of the rate dependence of pulse height for non-irradiated and irradiated pCVD diamond pad and pixel detectors, including detectors tested over a range of particle fluxes up to 20 MHz/cm2 with both pad and pixel readout electronics. Our test beam results indicate a 2% upper limit to the pulse height dependence of unirradiated and neutron irradiated pCVD diamond detectors leading to the conclusion that the pulse height in pCVD diamond detectors is, at most, minimally dependent on the particle flux.",

keywords = "3D diamond detectors, Chemical vapor deposition, Diamond detectors, Radiation tolerant detectors, pCVD diamond",

author = "M. Mali and M. Artuso and L. B{\"a}ni and M. Bartosik and V. Bellini and B. Bentele and P. Bergonzo and A. Bes and Brom, {J. M.} and G. Chiodini and D. Chren and V. Cindro and G. Claus and J. Collot and J. Cumalat and A. Dabrowski and D. Dauvergne and Tchernij, {S. Ditalia} and G. Eigen and V. Eremin and P. Everaere and J. Forneris and L. Gallin-Martel and Gallin-Martel, {M. L.} and Gan, {K. K.} and M. Gastal and A. Gentry and M. Goffe and J. Goldstein and A. Golubev and A. Gori{\v s}ek and E. Grigoriev and J. Grosse-Knetter and B. Hiti and D. Hits and C. Hoarau and M. Hoeferkamp and J. Hosslet and F. H{\"u}gging and C. Hutson and R. Jackman and R. Jennings-Moors and H. Kagan and K. Kanxheri and M. Kis and G. Kramberger and M. Kruger and S. Kuleshov and A. Lacoste and E. Lukosi and C. Maazouzi and I. Mandi{\'c} and S. Marcatili and A. Marino and C. Mathieu and M. Menichelli and M. Miku{\v z} and R. Molle and A. Morozzi and F. Moscatelli and J. Moss and R. Mountain and Muraz, {J. F.} and Narazyanan, {E. A.} and A. Oh and P. Olivero and D. Passeri and H. Pernegger and R. Perrino and F. Picollo and A. Porter and A. Portier and R. Potenza and A. Quadt and F. Rarbi and A. Re and M. Reichmann and S. Roe and O. Rossetto and P. Salter and Becerra, {D. A.Sanz} and Schmidt, {C. J.} and S. Schnetzer and S. Seidel and L. Servoli and R. Shivaraman and Smith, {D. S.} and B. Sopko and V. Sopko and J. Sorenson and S. Spagnolo and S. Spanier and K. Stenson and R. Stone and B. Stugu and C. Sutera and M. Traeger and W. Trischuk and M. Truccato and C. Tuve and J. Velthuis and E. Verbitskaya and S. Wagner and R. Wallny and J. Welch and T. Wengler and M. Yamouni and J. Zalieckas and M. Zavrtanik",

note = "Publisher Copyright: {\textcopyright} 2024 Elsevier B.V.",

year = "2024",

month = may,

doi = "10.1016/j.nima.2024.169202",

language = "English (US)",

volume = "1062",

journal = "Nuclear Instruments and Methods in Physics Research, Section A: Accelerators, Spectrometers, Detectors and Associated Equipment",

issn = "0168-9002",

publisher = "Elsevier B.V.",

}

Mali, M, Artuso, M, Bäni, L, Bartosik, M, Bellini, V, Bentele, B, Bergonzo, P, Bes, A, Brom, JM, Chiodini, G, Chren, D, Cindro, V, Claus, G, Collot, J, Cumalat, J, Dabrowski, A, Dauvergne, D, Tchernij, SD, Eigen, G, Eremin, V, Everaere, P, Forneris, J, Gallin-Martel, L, Gallin-Martel, ML, Gan, KK, Gastal, M, Gentry, A, Goffe, M, Goldstein, J, Golubev, A, Gorišek, A, Grigoriev, E, Grosse-Knetter, J, Hiti, B, Hits, D, Hoarau, C, Hoeferkamp, M, Hosslet, J, Hügging, F, Hutson, C, Jackman, R, Jennings-Moors, R, Kagan, H, Kanxheri, K, Kis, M, Kramberger, G, Kruger, M, Kuleshov, S, Lacoste, A, Lukosi, E, Maazouzi, C, Mandić, I, Marcatili, S, Marino, A, Mathieu, C, Menichelli, M, Mikuž, M, Molle, R, Morozzi, A, Moscatelli, F, Moss, J, Mountain, R, Muraz, JF, Narazyanan, EA, Oh, A, Olivero, P, Passeri, D, Pernegger, H, Perrino, R, Picollo, F, Porter, A, Portier, A, Potenza, R, Quadt, A, Rarbi, F, Re, A, Reichmann, M, Roe, S, Rossetto, O, Salter, P, Becerra, DAS, Schmidt, CJ, Schnetzer, S, Seidel, S, Servoli, L, Shivaraman, R, Smith, DS, Sopko, B, Sopko, V, Sorenson, J, Spagnolo, S, Spanier, S, Stenson, K, Stone, R, Stugu, B, Sutera, C, Traeger, M, Trischuk, W, Truccato, M, Tuve, C, Velthuis, J, Verbitskaya, E, Wagner, S, Wallny, R, Welch, J, Wengler, T, Yamouni, M, Zalieckas, J & Zavrtanik, M 2024, 'Latest results from the RD42 collaboration on the radiation tolerance of polycrystalline diamond detectors', Nuclear Instruments and Methods in Physics Research, Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, vol. 1062, 169202. https://doi.org/10.1016/j.nima.2024.169202

Latest results from the RD42 collaboration on the radiation tolerance of polycrystalline diamond detectors. / Mali, M.; Artuso, M.; Bäni, L. et al.
In: Nuclear Instruments and Methods in Physics Research, Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, Vol. 1062, 169202, 05.2024.

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

TY - JOUR

T1 - Latest results from the RD42 collaboration on the radiation tolerance of polycrystalline diamond detectors

AU - Mali, M.

AU - Artuso, M.

AU - Bäni, L.

AU - Bartosik, M.

AU - Bellini, V.

AU - Bentele, B.

AU - Bergonzo, P.

AU - Bes, A.

AU - Brom, J. M.

AU - Chiodini, G.

AU - Chren, D.

AU - Cindro, V.

AU - Claus, G.

AU - Collot, J.

AU - Cumalat, J.

AU - Dabrowski, A.

AU - Dauvergne, D.

AU - Tchernij, S. Ditalia

AU - Eigen, G.

AU - Eremin, V.

AU - Everaere, P.

AU - Forneris, J.

AU - Gallin-Martel, L.

AU - Gallin-Martel, M. L.

AU - Gan, K. K.

AU - Gastal, M.

AU - Gentry, A.

AU - Goffe, M.

AU - Goldstein, J.

AU - Golubev, A.

AU - Gorišek, A.

AU - Grigoriev, E.

AU - Grosse-Knetter, J.

AU - Hiti, B.

AU - Hits, D.

AU - Hoarau, C.

AU - Hoeferkamp, M.

AU - Hosslet, J.

AU - Hügging, F.

AU - Hutson, C.

AU - Jackman, R.

AU - Jennings-Moors, R.

AU - Kagan, H.

AU - Kanxheri, K.

AU - Kis, M.

AU - Kramberger, G.

AU - Kruger, M.

AU - Kuleshov, S.

AU - Lacoste, A.

AU - Lukosi, E.

AU - Maazouzi, C.

AU - Mandić, I.

AU - Marcatili, S.

AU - Marino, A.

AU - Mathieu, C.

AU - Menichelli, M.

AU - Mikuž, M.

AU - Molle, R.

AU - Morozzi, A.

AU - Moscatelli, F.

AU - Moss, J.

AU - Mountain, R.

AU - Muraz, J. F.

AU - Narazyanan, E. A.

AU - Oh, A.

AU - Olivero, P.

AU - Passeri, D.

AU - Pernegger, H.

AU - Perrino, R.

AU - Picollo, F.

AU - Porter, A.

AU - Portier, A.

AU - Potenza, R.

AU - Quadt, A.

AU - Rarbi, F.

AU - Re, A.

AU - Reichmann, M.

AU - Roe, S.

AU - Rossetto, O.

AU - Salter, P.

AU - Becerra, D. A.Sanz

AU - Schmidt, C. J.

AU - Schnetzer, S.

AU - Seidel, S.

AU - Servoli, L.

AU - Shivaraman, R.

AU - Smith, D. S.

AU - Sopko, B.

AU - Sopko, V.

AU - Sorenson, J.

AU - Spagnolo, S.

AU - Spanier, S.

AU - Stenson, K.

AU - Stone, R.

AU - Stugu, B.

AU - Sutera, C.

AU - Traeger, M.

AU - Trischuk, W.

AU - Truccato, M.

AU - Tuve, C.

AU - Velthuis, J.

AU - Verbitskaya, E.

AU - Wagner, S.

AU - Wallny, R.

AU - Welch, J.

AU - Wengler, T.

AU - Yamouni, M.

AU - Zalieckas, J.

AU - Zavrtanik, M.

PY - 2024/5

Y1 - 2024/5

N2 - As nuclear and particle physics facilities move to higher intensities, the detectors used there must be more radiation tolerant. Diamond is in use at many facilities due to its inherent radiation tolerance and ease of use. In this article we present our radiation tolerance measurements of the highest quality polycrystalline Chemical Vapor Deposition (pCVD) diamond material for irradiations from a range of proton energies, pions and neutrons up to a fluence of 2×1016particles/cm2. We have measured the damage constant as a function of energy and particle species and compared it with theoretical models. We also present measurements of the rate dependence of pulse height for non-irradiated and irradiated pCVD diamond pad and pixel detectors, including detectors tested over a range of particle fluxes up to 20 MHz/cm2 with both pad and pixel readout electronics. Our test beam results indicate a 2% upper limit to the pulse height dependence of unirradiated and neutron irradiated pCVD diamond detectors leading to the conclusion that the pulse height in pCVD diamond detectors is, at most, minimally dependent on the particle flux.

AB - As nuclear and particle physics facilities move to higher intensities, the detectors used there must be more radiation tolerant. Diamond is in use at many facilities due to its inherent radiation tolerance and ease of use. In this article we present our radiation tolerance measurements of the highest quality polycrystalline Chemical Vapor Deposition (pCVD) diamond material for irradiations from a range of proton energies, pions and neutrons up to a fluence of 2×1016particles/cm2. We have measured the damage constant as a function of energy and particle species and compared it with theoretical models. We also present measurements of the rate dependence of pulse height for non-irradiated and irradiated pCVD diamond pad and pixel detectors, including detectors tested over a range of particle fluxes up to 20 MHz/cm2 with both pad and pixel readout electronics. Our test beam results indicate a 2% upper limit to the pulse height dependence of unirradiated and neutron irradiated pCVD diamond detectors leading to the conclusion that the pulse height in pCVD diamond detectors is, at most, minimally dependent on the particle flux.

KW - 3D diamond detectors

KW - Chemical vapor deposition

KW - Diamond detectors

KW - Radiation tolerant detectors

KW - pCVD diamond

UR - http://www.scopus.com/inward/record.url?scp=85186358314&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=85186358314&partnerID=8YFLogxK

U2 - 10.1016/j.nima.2024.169202

DO - 10.1016/j.nima.2024.169202

M3 - Article

AN - SCOPUS:85186358314

SN - 0168-9002

VL - 1062

JO - Nuclear Instruments and Methods in Physics Research, Section A: Accelerators, Spectrometers, Detectors and Associated Equipment

JF - Nuclear Instruments and Methods in Physics Research, Section A: Accelerators, Spectrometers, Detectors and Associated Equipment

M1 - 169202

ER -

Latest results from the RD42 collaboration on the radiation tolerance of polycrystalline diamond detectors

Abstract

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