Optimum Energy Compensation for Current Mode Application of Silicon PIN Diode in Gamma Radiation Detection

A silicon PIN diode was modeled using the Monte Carlo transport code FLUKA. The code was utilized to identify a composite filter having two or more metals without any perforation, in order to flatten the diode's absorbed dose rate energy response in the photon energy range 60-1250 keV for DC mo...

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Veröffentlicht in:IEEE transactions on nuclear science 2016-12, Vol.63 (6), p.2777-2781
Hauptverfasser: Mitra, Pratip, Srivastava, Saurabh, Singh, Sunil K., Akar, D. K., Patni, H. K., Topkar, Anita, Vinod Kumar, A.
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container_issue 6
container_start_page 2777
container_title IEEE transactions on nuclear science
container_volume 63
creator Mitra, Pratip
Srivastava, Saurabh
Singh, Sunil K.
Akar, D. K.
Patni, H. K.
Topkar, Anita
Vinod Kumar, A.
description A silicon PIN diode was modeled using the Monte Carlo transport code FLUKA. The code was utilized to identify a composite filter having two or more metals without any perforation, in order to flatten the diode's absorbed dose rate energy response in the photon energy range 60-1250 keV for DC mode operation. The results were validated experimentally, confirming the utility of the diode for gamma radiation detection and monitoring for wide range of energies.
doi_str_mv 10.1109/TNS.2016.2622744
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subjects Detectors
Diodes
Dosage
Energy
Energy compensation
energy response
FLUKA
gamma radiation detection
Gamma rays
Gamma-ray detectors
Metals
Monte Carlo
Monte Carlo methods
Photonics
PIN diodes
PIN photodiodes
Silicon
silicon PIN diode
γ Radiation
title Optimum Energy Compensation for Current Mode Application of Silicon PIN Diode in Gamma Radiation Detection
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