Ústav technické a experimentální fyziky Institute of Experimental and Applied Physics

Extending the time-over-threshold calibration of Timepix3 for spatial-resolved ion spectroscopy

NázevTitle
Extending the time-over-threshold calibration of Timepix3 for spatial-resolved ion spectroscopyExtending the time-over-threshold calibration of Timepix3 for spatial-resolved ion spectroscopy
Druh výsledkuResult type
Článek v časopiseJournal article
AutořiAuthors
R. Mihai, B. Bergmann, P. Smolyanskiy
DOIDOI
10.1088/1748-0221/20/05/P05040
Časopis / citaceJournal / citation
Journal of Instrumentation. 2025, 20(5), ISSN 1748-0221.
RokYear
2025
JazykLanguage
eng
WoSWoS
001499944700001
ScopusScopus
2-s2.0-105006874529
RIVRIV
RIV/68407700:21670/25:00383938!RIV26-GA0-21670___
ProjektProject
Identifikace částic v experimentech fysiky vysokych energií a ve vesmíru s pokročilými detekčními systémyParticle identification in high-energy physics experiments and space with advanced detection systems

AbstraktAbstract

Hybrid pixel detectors have a well-established array of applications ranging from particle physics to life sciences. The small dimensions of Timepix3 as well as its relatively low energetic expenses make it an intriguing option additionally for ion detection in nuclear physics experiments, as it reveals simultaneously precise temporal, spatial and energetic properties of recorded events from nuclear reactions. Currently, a limiting factor is the electronics behavior at high input charge resulting in improper energy determination of incident heavier ions. While the low-energy per-pixel calibration of Timepix3 is normally performed with the use of photons of up to 60 keU, the characteristic linear range permits a correct extrapolation up to only 150 keU/pixel. We developed a global per-pixel energy correction method involving the use of short-ranged accelerated ions and spectroscopic alpha sources, to suitably extend the energy determination capability of Timepix3 for nuclear ion spectroscopy experiments, where spatial and temporal precision of recorded events are equally crucial. It was found that upon applying this correction, the reliable per-pixel energy range has been increased from the original 150 keU to at least 1.1 MeU, while maintaining the relative energy resolution to better than 2.5% for stopped protons of up to 1.9 MeU and better than 3.1% for alpha-particles of 5.5 MeU. Furthermore, to demonstrate the spatial resolution of Timepix3 detectors with silicon sensors, we present alpha-radiography measurements from which we extract the modulation transfer function (MTF) and produce real-world biological sample images.

Hybrid pixel detectors have a well-established array of applications ranging from particle physics to life sciences. The small dimensions of Timepix3 as well as its relatively low energetic expenses make it an intriguing option additionally for ion detection in nuclear physics experiments, as it reveals simultaneously precise temporal, spatial and energetic properties of recorded events from nuclear reactions. Currently, a limiting factor is the electronics behavior at high input charge resulting in improper energy determination of incident heavier ions. While the low-energy per-pixel calibration of Timepix3 is normally performed with the use of photons of up to 60 keU, the characteristic linear range permits a correct extrapolation up to only 150 keU/pixel. We developed a global per-pixel energy correction method involving the use of short-ranged accelerated ions and spectroscopic alpha sources, to suitably extend the energy determination capability of Timepix3 for nuclear ion spectroscopy experiments, where spatial and temporal precision of recorded events are equally crucial. It was found that upon applying this correction, the reliable per-pixel energy range has been increased from the original 150 keU to at least 1.1 MeU, while maintaining the relative energy resolution to better than 2.5% for stopped protons of up to 1.9 MeU and better than 3.1% for alpha-particles of 5.5 MeU. Furthermore, to demonstrate the spatial resolution of Timepix3 detectors with silicon sensors, we present alpha-radiography measurements from which we extract the modulation transfer function (MTF) and produce real-world biological sample images.