Modeling the Timing Characteristics of the PICOSEC Micromegas Detector

The PICOSEC Micromegas detector can time the arrival of Minimum Ionizing Particles with a sub-25 ps precision. A very good timing resolution in detecting single photons is also demonstrated in laser beams. The PICOSEC timing resolution is determined mainly by the drift field. The arrival time of the...

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Detalles Bibliográficos
Autores principales: Bortfeldt, J., Brunbauer, F., David, C., Desforge, D., Fanourakis, G., Gallinaro, M., García, F., Giomataris, I., Gustavsson, T., Iguaz, F.J., Kebbiri, M., Kordas, K., Lampoudis, C., Legou, P., Lisowska, M., Liu, J., Lupberger, M., Maillard, O., Manthos, I., Müller, H., Niaouris, V., Oliveri, E., Papaevangelou, T., Paraschou, K., Pomorski, M., Qi, B., Resnati, F., Ropelewski, L., Sampsonidis, D., Scharenberg, L., Schneider, T., Sohl, L., van Stenis, M., Tsipolitis, Y., Tzamarias, S.E., Utrobicic, A., Veenhof, R., Wang, X., White, S., Zhang, Z., Zhou, Y.
Lenguaje:eng
Publicado: 2019
Materias:
physics.ins-det
Detectors and Experimental Techniques
Acceso en línea:https://dx.doi.org/10.1016/j.nima.2021.165049
http://cds.cern.ch/record/2655560
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author Bortfeldt, J.
Brunbauer, F.
David, C.
Desforge, D.
Fanourakis, G.
Gallinaro, M.
García, F.
Giomataris, I.
Gustavsson, T.
Iguaz, F.J.
Kebbiri, M.
Kordas, K.
Lampoudis, C.
Legou, P.
Lisowska, M.
Liu, J.
Lupberger, M.
Maillard, O.
Manthos, I.
Müller, H.
Niaouris, V.
Oliveri, E.
Papaevangelou, T.
Paraschou, K.
Pomorski, M.
Qi, B.
Resnati, F.
Ropelewski, L.
Sampsonidis, D.
Scharenberg, L.
Schneider, T.
Sohl, L.
van Stenis, M.
Tsipolitis, Y.
Tzamarias, S.E.
Utrobicic, A.
Veenhof, R.
Wang, X.
White, S.
Zhang, Z.
Zhou, Y.
author_facet Bortfeldt, J.
Brunbauer, F.
David, C.
Desforge, D.
Fanourakis, G.
Gallinaro, M.
García, F.
Giomataris, I.
Gustavsson, T.
Iguaz, F.J.
Kebbiri, M.
Kordas, K.
Lampoudis, C.
Legou, P.
Lisowska, M.
Liu, J.
Lupberger, M.
Maillard, O.
Manthos, I.
Müller, H.
Niaouris, V.
Oliveri, E.
Papaevangelou, T.
Paraschou, K.
Pomorski, M.
Qi, B.
Resnati, F.
Ropelewski, L.
Sampsonidis, D.
Scharenberg, L.
Schneider, T.
Sohl, L.
van Stenis, M.
Tsipolitis, Y.
Tzamarias, S.E.
Utrobicic, A.
Veenhof, R.
Wang, X.
White, S.
Zhang, Z.
Zhou, Y.
author_sort Bortfeldt, J.
collection CERN
description The PICOSEC Micromegas detector can time the arrival of Minimum Ionizing Particles with a sub-25 ps precision. A very good timing resolution in detecting single photons is also demonstrated in laser beams. The PICOSEC timing resolution is determined mainly by the drift field. The arrival time of the signal and the timing resolution vary with the size of the pulse amplitude.Detailed simulations based on GARFIELD++ reproduce the experimental PICOSEC timing characteristics. This agreement is exploited to identify the microscopic physical variables, which determine the observed timing properties. In these studies, several counter-intuitive observations are made for the behavior of such microscopic variables. In order to gain insight on the main physical mechanisms causing the observed behavior, a phenomenological model is constructed and presented. The model is based on a simple mechanism of “time-gain per interaction” and it employs a statistical description of the avalanche evolution. It describes quantitatively the dynamical and statistical properties of the microscopic quantities, which determine the PICOSEC timing characteristics, in excellent agreement with the simulations. In parallel, it offers phenomenological explanations for the behavior of these microscopic variables. The formulae expressing this model can be used as a tool for fast and reliable predictions, provided that the input parameter values (e.g. drift velocities) are known for the considered operating conditions.
id cern-2655560
institution Organización Europea para la Investigación Nuclear
language eng
publishDate 2019
record_format invenio
spelling cern-26555602023-03-14T19:20:12Zdoi:10.1016/j.nima.2021.165049http://cds.cern.ch/record/2655560engBortfeldt, J.Brunbauer, F.David, C.Desforge, D.Fanourakis, G.Gallinaro, M.García, F.Giomataris, I.Gustavsson, T.Iguaz, F.J.Kebbiri, M.Kordas, K.Lampoudis, C.Legou, P.Lisowska, M.Liu, J.Lupberger, M.Maillard, O.Manthos, I.Müller, H.Niaouris, V.Oliveri, E.Papaevangelou, T.Paraschou, K.Pomorski, M.Qi, B.Resnati, F.Ropelewski, L.Sampsonidis, D.Scharenberg, L.Schneider, T.Sohl, L.van Stenis, M.Tsipolitis, Y.Tzamarias, S.E.Utrobicic, A.Veenhof, R.Wang, X.White, S.Zhang, Z.Zhou, Y.Modeling the Timing Characteristics of the PICOSEC Micromegas Detectorphysics.ins-detDetectors and Experimental TechniquesThe PICOSEC Micromegas detector can time the arrival of Minimum Ionizing Particles with a sub-25 ps precision. A very good timing resolution in detecting single photons is also demonstrated in laser beams. The PICOSEC timing resolution is determined mainly by the drift field. The arrival time of the signal and the timing resolution vary with the size of the pulse amplitude.Detailed simulations based on GARFIELD++ reproduce the experimental PICOSEC timing characteristics. This agreement is exploited to identify the microscopic physical variables, which determine the observed timing properties. In these studies, several counter-intuitive observations are made for the behavior of such microscopic variables. In order to gain insight on the main physical mechanisms causing the observed behavior, a phenomenological model is constructed and presented. The model is based on a simple mechanism of “time-gain per interaction” and it employs a statistical description of the avalanche evolution. It describes quantitatively the dynamical and statistical properties of the microscopic quantities, which determine the PICOSEC timing characteristics, in excellent agreement with the simulations. In parallel, it offers phenomenological explanations for the behavior of these microscopic variables. The formulae expressing this model can be used as a tool for fast and reliable predictions, provided that the input parameter values (e.g. drift velocities) are known for the considered operating conditions.The PICOSEC Micromegas detector can time the arrival of Minimum Ionizing Particles with a sub-25 ps precision. A very good timing resolution in detecting single photons is also demonstrated in laser beams. The PICOSEC timing resolution is determined mainly by the drift field. The arrival time of the signal and the timing resolution vary with the size of the pulse amplitude. Detailed simulations based on GARFIELD++ reproduce the experimental PICOSEC timing characteristics. This agreement is exploited to identify the microscopic physical variables, which determine the observed timing properties. In these studies, several counter-intuitive observations are made for the behavior of such microscopic variables. In order to gain insight on the main physical mechanisms causing the observed behavior, a phenomenological model is constructed and presented. The model is based on a simple mechanism of "time-gain per interaction" and it employs a statistical description of the avalanche evolution. It describes quantitatively the dynamical and statistical properties of the microscopic quantities, which determine the PICOSEC timing characteristics, in excellent agreement with the simulations. In parallel, it offers phenomenological explanations for the behavior of these microscopic variables. The formulae expressing this model can be used as a tool for fast and reliable predictions, provided that the input parameter values (e.g. drift velocities) are known for the considered operating conditions.arXiv:1901.10779oai:cds.cern.ch:26555602019-01-30
spellingShingle physics.ins-det
Detectors and Experimental Techniques
Bortfeldt, J.
Brunbauer, F.
David, C.
Desforge, D.
Fanourakis, G.
Gallinaro, M.
García, F.
Giomataris, I.
Gustavsson, T.
Iguaz, F.J.
Kebbiri, M.
Kordas, K.
Lampoudis, C.
Legou, P.
Lisowska, M.
Liu, J.
Lupberger, M.
Maillard, O.
Manthos, I.
Müller, H.
Niaouris, V.
Oliveri, E.
Papaevangelou, T.
Paraschou, K.
Pomorski, M.
Qi, B.
Resnati, F.
Ropelewski, L.
Sampsonidis, D.
Scharenberg, L.
Schneider, T.
Sohl, L.
van Stenis, M.
Tsipolitis, Y.
Tzamarias, S.E.
Utrobicic, A.
Veenhof, R.
Wang, X.
White, S.
Zhang, Z.
Zhou, Y.
Modeling the Timing Characteristics of the PICOSEC Micromegas Detector
title Modeling the Timing Characteristics of the PICOSEC Micromegas Detector
title_full Modeling the Timing Characteristics of the PICOSEC Micromegas Detector
title_fullStr Modeling the Timing Characteristics of the PICOSEC Micromegas Detector
title_full_unstemmed Modeling the Timing Characteristics of the PICOSEC Micromegas Detector
title_short Modeling the Timing Characteristics of the PICOSEC Micromegas Detector
title_sort modeling the timing characteristics of the picosec micromegas detector
topic physics.ins-det
Detectors and Experimental Techniques
url https://dx.doi.org/10.1016/j.nima.2021.165049
http://cds.cern.ch/record/2655560
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