On the limit of the accuracy of timе stamp at the detection of annihilation γ-quanta with a scintillation detector

Authors

  • Mikhail V. Korzhik Institute for Nuclear Problems, Belarusian State University, 11 Babrujskaja Street, Minsk 220006, Belarus

Keywords:

scintillator, time resolution, relaxation, cerium, lead tungstate

Abstract

An influence of the various relaxation processes of the electronic excitations causing the scintillation in the crystalline compounds under ionising radiation is analysed. It was found that the intracenter relaxation of electronic excitations in the luminescence ion forms a physical limit for the time resolution of the scintillation detector. The limit of the time resolution, which can be provided when measuring the ionising radiation with a scintillation detector, has been established by simulation. A comparison of the time resolution limits for various errors by the electronic part of the ionising radiation detector is performed. It is shown that inorganic scintillation materials based on single crystals activated by cerium ions have a limit of 10 ps, while self-activated scintillators with low yield and short scintillation kinetics may show results not worse than 20 ps. It has been demonstrated that a further increase in the scintillation yield while keeping the short kinetics in self-activated materials can provide a better time resolution in comparison with Ce-activated materials in future detectors.

Author Biography

  • Mikhail V. Korzhik, Institute for Nuclear Problems, Belarusian State University, 11 Babrujskaja Street, Minsk 220006, Belarus

    doctor of science (physics and mathematics); head of the laboratory of experimental high energy physics

References

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Published

2021-05-25

Issue

Section

Atomic Nucleus and Elementary Particle Physics

How to Cite

(1)
Korzhik, M. V. On the Limit of the Accuracy of Timе Stamp at the Detection of Annihilation γ-Quanta With a Scintillation Detector. Журнал Белорусского государственного университета. Физика 2021, No. 2, 96-101. https://doi.org/10.33581/2520-2243-2021-2-96-101.