Channels of Energy Losses and Relaxation in CsI:A Scintillators ( =, In)

Radiative relaxation channels and energy losses in In and Tl doped CsI scintillation crystals have been investigated as a function of temperature and excitation conditions to evaluate scintillation efficiency of the activator channel. Two activator concentration series of crystals were grown by the...

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Published in:IEEE transactions on nuclear science 2014-02, Vol.61 (1), p.246-251
Main Authors: Gridin, Sergii S., Belsky, Andrei N., Shiran, Natalia V., Gektin, Alex V.
Format: Article
Language:English
Subjects:
Activator
Bridgman method
Channels
Charge carrier processes
Charge carriers
Chemical Sciences
crystal
Crystals
Energy (nuclear)
Energy loss
Engineering Sciences
Excitation
light yield
Luminescence
Migration
Physics
scintillator
Spontaneous emission
Temperature
Temperature dependence
Temperature measurement
Trapping
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cited_by cdi_FETCH-LOGICAL-c358t-c68130fd0ccb4df0e95def51efb52eb7f34bbd32c12d42dcd47bb0a9eecc7bae3
cites cdi_FETCH-LOGICAL-c358t-c68130fd0ccb4df0e95def51efb52eb7f34bbd32c12d42dcd47bb0a9eecc7bae3
container_end_page 251
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container_title IEEE transactions on nuclear science
container_volume 61
creator Gridin, Sergii S.
Belsky, Andrei N.
Shiran, Natalia V.
Gektin, Alex V.
description Radiative relaxation channels and energy losses in In and Tl doped CsI scintillation crystals have been investigated as a function of temperature and excitation conditions to evaluate scintillation efficiency of the activator channel. Two activator concentration series of crystals were grown by the Bridgman method. Temperature dependence of excitation and luminescence spectra were measured under VUV and X-ray excitation; thermostimulated luminescence was also studied. The observed drop of radioluminescence yield of doped CsI crystals at room temperature relative to the pure crystal is explained by the migration losses caused by charge carrier trapping on the activator centers. The energy losses in CsI:A at low temperatures are due to the trapping of charge carriers on different centers: self-trapping of holes and capture of electrons by the activator centers. We suppose that migration energy losses are the main reason for significantly lower luminescence yield of CsI:A at room temperature than that of self-trapped excitons in pure CsI crystal.
doi_str_mv 10.1109/TNS.2013.2283316
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Two activator concentration series of crystals were grown by the Bridgman method. Temperature dependence of excitation and luminescence spectra were measured under VUV and X-ray excitation; thermostimulated luminescence was also studied. The observed drop of radioluminescence yield of doped CsI crystals at room temperature relative to the pure crystal is explained by the migration losses caused by charge carrier trapping on the activator centers. The energy losses in CsI:A at low temperatures are due to the trapping of charge carriers on different centers: self-trapping of holes and capture of electrons by the activator centers. 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source IEEE Xplore (Online service)
subjects Activator
Bridgman method
Channels
Charge carrier processes
Charge carriers
Chemical Sciences
crystal
Crystals
Energy (nuclear)
Energy loss
Engineering Sciences
Excitation
light yield
Luminescence
Migration
Physics
scintillator
Spontaneous emission
Temperature
Temperature dependence
Temperature measurement
Trapping
title Channels of Energy Losses and Relaxation in CsI:A Scintillators ( =, In)
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