Monte Carlo Calculation of linear attenuation coefficients and photon scattering properties of novel concretes loaded with Osmium, Iridium and Barite nanoparticles

Recent studies have shown that the use of high-density nanoparticles (NPs) in concrete composition improves its radiation shielding properties. In the present study, the linear attenuation coefficients and photon scattering properties of newly developed high-density Nano-concretes have been calculat...

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Bibliographic Details
Published inPolish journal of medical physics and engineering Vol. 27; no. 4; pp. 291 - 298
Main Authors Jou, Samira Keramat, Mesbahi, Asghar, Zamiri, Reza Eghdam, Seyednejad, Farshad
Format Journal Article
LanguageEnglish
Published Warsaw Sciendo 01.12.2021
De Gruyter Poland
Subjects
Atomic properties
Attenuation coefficients
Barite
composite shield
Concrete
Electron density
Iridium
linear attenuation coefficient
Mathematical analysis
MCNPX
Monte Carlo simulation
Nanoparticles
Osmium
Photon beams
Photon scatter
Photons
Radiation shielding
Scattering
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Summary:Recent studies have shown that the use of high-density nanoparticles (NPs) in concrete composition improves its radiation shielding properties. In the present study, the linear attenuation coefficients and photon scattering properties of newly developed high-density Nano-concretes have been calculated using the MCNPX Monte Carlo code. The shielding properties of Nano-concretes containing 10%, 20%, and 30% weight percentage of Osmium, Iridium and Barite NPs (100 nm) as well as ordinary concrete were investigated. The 6 and 18 MV photon beams of Varian Linac and photons were used for simulation. Photon scattering flux was calculated for all Nano-concretes with 30 wt% of NPs and ordinary concrete at different angles. In general, by adding Iridium, Osmium and Barite NPs to ordinary concrete, the linear attenuation coefficients increased. Despite a lower density relative to Iridium and Osmium, Nano-concretes containing Barite exhibited a higher linear attenuation coefficient due to their higher electron density. The results revealed a dependence between the scattered photon flux and the effective atomic number of Nano-concretes. With increasing the atomic number of fillers, the intensity of the scattered photon flux enlarged. Also, the scattered flux was higher for all types of concretes at 180 degrees relative to other angles.
ISSN:1898-0309
1425-4689
1898-0309
DOI:10.2478/pjmpe-2021-0034