Design and Simulation of Liquid Krypton as Gamma Ray Detector

Author

Hassan, Syed Minhaj ; Hassanein, A. ; Koltick, D.S. ; Satvat, N. ; Xue Yang

Author_Institution

Sch. of Nucl. Eng., Purdue Univ., West Lafayette, IN, USA

Volume

60

Issue

2

fYear

2013

fDate

Apr-13

Firstpage

658

Lastpage

661

Abstract

Monte Carlo simulations were used to model gamma ray interactions at 1 MeV and 11 MeV within liquid krypton to understand geometry effects and energy containment. Two Monte Carlo codes were used in this work: Geant4 and MCNP5. The agreement of the two codes was shown by the comparison of the calculated average energy deposition and fraction of incident gamma energy deposited as a function of chamber lengths and gamma ray offsets. Modeling shows that good energy containment for 1 MeV gamma rays occurs for chamber depths of 20 cm. For gamma rays entering parallel to the central axis of the detector, 1 MeV showers are well contained up to approximately 1 cm of the detectors´ edge. For 11 MeV gamma rays the acceptance plateau occurs at a depth of 40 cm and 20 cm from the detectors´ edge.

Keywords

Monte Carlo methods; gamma-ray detection; germanium radiation detectors; krypton; nuclear engineering computing; nuclear materials safeguards; Geant4 code; Kr; MCNP5 code; Monte Carlo simulations; average energy deposition; central axis; chamber depths; depth 20 cm; depth 40 cm; electron volt energy 1 MeV; electron volt energy 11 MeV; energy containment; gamma ray detector; gamma ray interactions; gamma ray offsets; geometry effect; incident gamma energy; liquid krypton; Detectors; Gamma-ray detectors; Gamma-rays; Libraries; Liquids; Photonics; Physics; Gamma ray detector; Geant4; MCNP5; Monte Carlo simulation; liquid krypton; liquid noble gas;

fLanguage

English

Journal_Title

Nuclear Science, IEEE Transactions on

Publisher

ieee

ISSN

0018-9499

Type

jour

DOI

10.1109/TNS.2013.2252195

Filename

6496297