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Auteurs principaux: Knopf, Matthias, Waid, Simon, Gundacker, Stefan, Onder, Sebastian, Radmanovac, Daniel, Gaggl, Philipp, Bordieri, Giulio, Cordoni, Francesco, Missiaggia, Marta, Verroi, Enrico, Magrin, Giulio, Bergauer, Thomas, Hirtl, Albert
Format: Preprint
Publié: 2026
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Accès en ligne:https://arxiv.org/abs/2605.07508
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author Knopf, Matthias
Waid, Simon
Gundacker, Stefan
Onder, Sebastian
Radmanovac, Daniel
Gaggl, Philipp
Bordieri, Giulio
Cordoni, Francesco
Missiaggia, Marta
Verroi, Enrico
Magrin, Giulio
Bergauer, Thomas
Hirtl, Albert
author_facet Knopf, Matthias
Waid, Simon
Gundacker, Stefan
Onder, Sebastian
Radmanovac, Daniel
Gaggl, Philipp
Bordieri, Giulio
Cordoni, Francesco
Missiaggia, Marta
Verroi, Enrico
Magrin, Giulio
Bergauer, Thomas
Hirtl, Albert
contents Detector characterization and instrumentation testing are often performed at cyclotron and synchrotron facilities, many of which were originally developed for medical applications in cancer therapy. For particle physics experiments requiring a single-particle resolution, pileup can significantly degrade data quality, making precise knowledge of the beam time structure essential for selecting appropriate readout parameters. However, such information is often unavailable from the facilities and challenging to determine experimentally. Here, we report measurements of the spill time structure at two medical accelerator facilities using a silicon carbide (SiC) particle sensor coupled to a high-frequency readout system. Owing to its high carrier saturation velocity and the tolerance to large bias voltages, SiC is well suited for fast readout and measurements requiring precise timing. Using a 6 GHz readout with custom SiC diodes, we characterize the micro-spill structure of both cyclotron and synchrotron beams on a sub-nanosecond timescale. The measured arrival-time distributions exhibit modulation with the accelerator RF frequencies, reflecting features of the extraction process. The resolved micro-spill structure enables quantitative estimation of pileup contributions and provides design constraints for future readout electronics. The presented results emphasize the importance of the characterization of the beam time-structure characterization for the development of precise readout systems.
format Preprint
id arxiv_https___arxiv_org_abs_2605_07508
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Measurements of the micro-spill structure of medical cyclotron and synchrotron beams and its impact on pulse pileup
Knopf, Matthias
Waid, Simon
Gundacker, Stefan
Onder, Sebastian
Radmanovac, Daniel
Gaggl, Philipp
Bordieri, Giulio
Cordoni, Francesco
Missiaggia, Marta
Verroi, Enrico
Magrin, Giulio
Bergauer, Thomas
Hirtl, Albert
Instrumentation and Detectors
High Energy Physics - Experiment
Detector characterization and instrumentation testing are often performed at cyclotron and synchrotron facilities, many of which were originally developed for medical applications in cancer therapy. For particle physics experiments requiring a single-particle resolution, pileup can significantly degrade data quality, making precise knowledge of the beam time structure essential for selecting appropriate readout parameters. However, such information is often unavailable from the facilities and challenging to determine experimentally. Here, we report measurements of the spill time structure at two medical accelerator facilities using a silicon carbide (SiC) particle sensor coupled to a high-frequency readout system. Owing to its high carrier saturation velocity and the tolerance to large bias voltages, SiC is well suited for fast readout and measurements requiring precise timing. Using a 6 GHz readout with custom SiC diodes, we characterize the micro-spill structure of both cyclotron and synchrotron beams on a sub-nanosecond timescale. The measured arrival-time distributions exhibit modulation with the accelerator RF frequencies, reflecting features of the extraction process. The resolved micro-spill structure enables quantitative estimation of pileup contributions and provides design constraints for future readout electronics. The presented results emphasize the importance of the characterization of the beam time-structure characterization for the development of precise readout systems.
title Measurements of the micro-spill structure of medical cyclotron and synchrotron beams and its impact on pulse pileup
topic Instrumentation and Detectors
High Energy Physics - Experiment
url https://arxiv.org/abs/2605.07508