Determination of Radiation Shielding Features of Polyvinyl Alcohol/Magnetite-Bismuth Oxide Composite Using Precise Computational Methods and Monte Carlo Code

Fariba Baroonzadeh; Maziyar Mahdavi; Mohammad Hosseini; Reza Jalli

Determination of Radiation Shielding Features of Polyvinyl Alcohol/Magnetite-Bismuth Oxide Composite Using Precise Computational Methods and Monte Carlo Code

محل انتشار: مجله فیزیک پزشکی ایران، دوره: 21، شماره: 6

سال انتشار: 1403

نوع سند: مقاله ژورنالی

زبان: انگلیسی

مشاهده: 59

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https://civilica.com/doc/2202974

شناسه ملی سند علمی:

JR_IJMP-21-6_005

تاریخ نمایه سازی: 26 اسفند 1403

چکیده مقاله:

Introduction: Bismuth efficiency in shielding superficial tissues in computed tomography (CT) scans has been challenged due to the imbalance between image quality and dose reduction. The aim of this study is to reduce bismuth in shields and investigate the possibility of substitution with lower atomic materials. Material and Methods: Five different compounds, including raw polyvinyl alcohol (PVA) and four other samples containing variable weight fractions of bismuth oxide and with a constant fraction of magnetite were selected. Shielding factors, including linear attenuation coefficient(μ), mass attenuation coefficient(μρ), half-value layer (HVL), electron density (Ne), and effective atomic number (Zeff), were evaluated over a wide range of energy by precise computational methods, XCOM, and Monte Carlo N-Particle code. Results: Increasing the bismuth oxide concentration improves the radiation attenuation and absorption process. This effect was observed in the μρ graphs to medium energies (E < ۰.۳۵۶۰ MeV).The simultaneous evaluation of Ne and Zeff predicts increased absorption due to the increased and dominant photoelectric effect (<۰.۱۰۰۰ MeV), the raised Compton effect (۰.۱۰۰۰ < E < ۰.۳۵۶۰ MeV; followed by scattering owing to the predominant Compton effect), and formation (E ≈ ۱.۲۲۰۰ MeV)and dominance of pair production phenomenon (E > ۳.۰۰۰۰ MeV).Also, a quantitative analysis of absorption through HVL in several used energies showed the efficacy of these compounds in ionizing radiation absorption. Conclusion: This study establishes the advantages of substituting bismuth with compounds having lower atomic number materials, and the possibility of alleviating bismuth and replacing it with magnetite and PVA in designing radiation shields in CT scans has been confirmed.

کلیدواژه ها:

Polyvinyl alcohol ، Magnetite ، Bismuth oxide ، Shield ، Computed Tomography (CT) ، MCNP code

نویسندگان

Fariba Baroonzadeh

Department of Radiology, School of Paramedical Sciences, Shiraz University of Medical Sciences, Shiraz, Iran.

Maziyar Mahdavi

۱-Radiology Department, Faculty of Paramedical Sciences, Shiraz University of Medical Sciences. Shiraz, Iran ۲-Ionizing and Non-Ionizing Radiation Protection Research Center (INIRPRC), School of Paramedical Sciences, Shiraz University

Mohammad Hosseini

Ionizing and Non-Ionizing Radiation Protection Research Center (INIRPRC), School of Paramedical Sciences, Shiraz University of Medical Sciences, Shiraz, Iran. &dagger; Now at Physics Department, Università degli Studi di Torino,

Reza Jalli

Medical imaging research center, Shiraz university of medical sciences, Shiraz, Iran

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Cember H, Johnson T. Introduction to Health Physics. ۴th ed., ...
Chilton AB, Shultis JK, Faw RE. Principles of radiation shielding. ...
Nambiar S, Yeow JT. Polymer-composite materials for radiation protection. ACS ...
More CV, Alsayed Z, Badawi M, Thabet A, Pawar PP. ...
Ambika MR, Nagaiah N, Suman SK. Role of bismuth oxide ...
Mehrara R, Malekie S, Kotahi SM, Kashian S. Introducing a ...
Hosseini MA, Malekie S, Kazemi F. Experimental evaluation of gamma ...
Hosseini MA, Kazemi F, Malekie S. A Monte Carlo study ...
Noor Azman NZ, Musa NF, Nik Ab Razak NN, Ramli ...
Brenner DJ, Hall EJ. Computed tomography—an increasing source of radiation ...
Mathews JD, Forsythe AV, Brady Z, Butler MW, Goergen SK, ...
Dellie ST, Tesfaw AF. Evaluation of Local Diagnostic Reference Levels ...
Abyar M, Mahdavi M, Haddadi GH. Establishing local Diagnostic Reference ...
Okoro NO, Changizi V, Bagh EJ, Pak F. Optimization of ...
Asadinezhad M, Bahreyni Toossi MT, Nouri M. Diagnostic reference levels ...
Bahreyni Toossi MT, Zare H, Eslami Z, Bayani Roodi S, ...
Mehnati P, Malekzadeh R, Sooteh MY. Use of bismuth shield ...
Kawauchi S, Chida K, Moritake T, Hamada Y, Tsuruta W. ...
Kim MS, Choi J, Kim SY, Kweon DC. Adaptive statistical ...
Einstein AJ, Elliston CD, Groves DW, Cheng B, Wolff SD, ...
McCollough CH, Wang J, Gould RG, Orton CG. The use ...
Durante M. Space radiation protection: destination Mars. Life Sci Space ...
Daneshvar H, Milan KG, Sadr A, Sedighy SH, Malekie S, ...
Sun J, Zhou S, Hou P, Yang Y, Weng J, ...
Arsalani N, Fattahi H, Nazarpoor M. Synthesis and characterization of ...
Oltolina F, Peigneux A, Colangelo D, Clemente N, D’Urso A, ...
Yew YP, Shameli K, Miyake M, Khairudin NB, Mohamad SE, ...
DeMerlis CC, Schoneker DR. Review of the oral toxicity of ...
Baker MI, Walsh SP, Schwartz Z, Boyan BD. A review ...
Srinivasan K, Samuel EJ. Evaluation of radiation shielding properties of ...
Hosseini M, Malekie S, Keshavarzi M. Analysis of radiation shielding ...
Hashim A, Agool IR, Kadhim KJ. Novel of (polymer blend-Fe۳O۴) ...
Issa SA, Ahmad M, Tekin HO, Saddeek YB, Sayyed MI. ...
Elmahroug Y, Almatari M, Sayyed MI, Dong MG, Tekin HO. ...
ASTM Committee D-۲۰ on Plastics. Standard test methods for density ...
Pellowitz D. MCNPX User’s Manual, version ۲.۶.۰. Los Alamos Report ...
Tekin HO. MCNP-X Monte Carlo code application for mass attenuation ...
NIST XCOM. Element/compound/mixture—physical measurement. National Institute of Standards and Technology. ...
Hubbell J. Photon cross sections, attenuation coefficients and energy absorption ...
Manohara SR, Hanagodimath SM, Gerward L. Energy dependence of effective ...
Manohara SR, Hanagodimath SM, Thind KS, Gerward L. On the ...
Büyükyıldız M. Effective atomic numbers and electron densities for some ...
Akyildirim H. Attenuation parameters and effective atomic numbers of concretes ...
Kucuk N, Cakir M, Isitman NA. Mass attenuation coefficients, effective ...
Taylor ML, Smith RL, Dossing F, Franich RD. Robust calculation ...
Olad A, Shakoori S. Electromagnetic interference attenuation and shielding effect ...
Chen Y, Wang Y, Zhang HB, Li X, Gui CX, ...
Huangfu Y, Liang C, Han Y, Qiu H, Song P, ...
Saba V, Keshtkar M. Targeted radiation energy modulation using Saba ...
Keshtkar M, Blouri B, Mahmoudabadi A, Alami A. Eye radiation ...
Van Elmpt W, Landry G, Das M, Verhaegen F. Dual ...

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