Monte Carlo calculation of organ dose coefficients for internal dosimetry: Results of an international intercomparison exercise

EURADOS Working Group 6 has organized an intercomparison exercise on the use of the ICRP Reference Computational Phantoms with radiation transport codes. This paper summarizes the results of a specific task from the intercomparison exercise modelling internal radiation sources. The quantities to be...

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Published in:Radiation measurements 2021-11, Vol.148, p.106661, Article 106661
Main Authors: Zankl, Maria, Gómez Ros, José-María, Moraleda, Montserrat, Reichelt, Uwe, Akar, Deepak K., Borbinha, Jorge, Desorgher, Laurent, Di Maria, Salvatore, EL Bakkali, Jaafar, Fantinova, Karin, Ferrari, Paolo, Gossio, Sebastian, Hunt, John, Jovanovic, Zoran, Kim, Han Sung, Krstic, Dragana, Lee, Yi-Kang, Nadar, Minal Y., Nikezic, Dragoslav, Patni, Hemant K., Murugan, Manohari, Triviño, Sebastian
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Intercomparison exercise
Internal dosimetry
Monte Carlo
Reference phantoms
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creator Zankl, Maria
Gómez Ros, José-María
Moraleda, Montserrat
Reichelt, Uwe
Akar, Deepak K.
Borbinha, Jorge
Desorgher, Laurent
Di Maria, Salvatore
EL Bakkali, Jaafar
Fantinova, Karin
Ferrari, Paolo
Gossio, Sebastian
Hunt, John
Jovanovic, Zoran
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Lee, Yi-Kang
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Nikezic, Dragoslav
Patni, Hemant K.
Murugan, Manohari
Triviño, Sebastian
description EURADOS Working Group 6 has organized an intercomparison exercise on the use of the ICRP Reference Computational Phantoms with radiation transport codes. This paper summarizes the results of a specific task from the intercomparison exercise modelling internal radiation sources. The quantities to be calculated were absorbed fractions and specific absorbed fractions for monoenergetic photon and electron sources as well as S-values for two radionuclides in four source organs. Twelve participants from eleven countries participated in this specific task using the Monte Carlo radiation transport codes FLUKA, Geant4, the MCNP code family, PenEasy, TRIPOLI-4 and VMC. Although some participants provided initial solutions in good agreement with the master solution evaluated by the organizers, differences of factors or even orders of magnitude were also found. Following feedback from the organizer, most participants submitted revised solutions that were mostly in better agreement with the master solution, although this was not always the case. Some initial and revised results are discussed in detail in this paper, and the reasons of mistakes are described as far as they were revealed by the participants. A full account of all results is presented in specific annexes as supplemental material. •EURADOS has organized an intercomparison study on the use of the ICRP/ICRU reference computational phantoms.•This article deals with one task involving internal sources.•Some participants provided solutions in agreement with the master solution, but large differences were also found.•Following feedback from the organizer, most participants submitted revised solutions that were mostly in better agreement.•It has been confirmed that intercomparison exercises are valuable for establishing good practice in computational dosimetry.
doi_str_mv 10.1016/j.radmeas.2021.106661
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subjects Intercomparison exercise
Internal dosimetry
Monte Carlo
Reference phantoms
title Monte Carlo calculation of organ dose coefficients for internal dosimetry: Results of an international intercomparison exercise
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