A comparative study between nano-cadmium oxide and lead oxide reinforced in high density polyethylene as gamma rays shielding composites

In this work, polymer composites of high density polyethylene reinforced by micro-sized and nanosized cadmium oxide, lead oxide, and a mixture of both with filler weight fraction of 30% were prepared by compression molding technique and characterized by scanning electron microscope. This investigati...

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Published in	Nuclear technology & radiation protection Vol. 35; no. 1; pp. 42 - 49
Main Authors	Alharshan, Gharam, Aloraini, Dalal, Elzaher, Mohamed, Badawi, Mohamed, Alabsy, Mahmoud, Abbas, Mahmoud, El-Khatib, Ahmed
Format	Journal Article
Language	English
Published	Belgrade Vinca Institute of Nuclear Sciences 01.01.2020 VINCA Institute of Nuclear Sciences
Subjects	Attenuation coefficients Cadmium Cesium 137 Cesium isotopes Comparative studies Fillers gamma radiation shielding Gamma rays Germanium high density polyethylene composites High density polyethylenes Lead oxides linear attenuation coefficient Mathematical analysis nano-cadmium oxide nano-lead oxide Point sources Polyethylene Polymer matrix composites Pressure molding Radiation shielding Weight
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Abstract	In this work, polymer composites of high density polyethylene reinforced by micro-sized and nanosized cadmium oxide, lead oxide, and a mixture of both with filler weight fraction of 30% were prepared by compression molding technique and characterized by scanning electron microscope. This investigation aims to present a comparative study between cadmium oxide and lead oxide according to their sizes as fillers in high density polyethylene polymeric matrix for gamma-radiation shielding applications. The mass and linear attenuation coefficients of the investigated composites were measured as a function of g-ray energies ranging from 59.53 keV to 1408.01 keV using standard radioactive point sources (241Am, 133Ba, 137Cs, 60Co, and 152Eu). The measurements were made with a narrow beam geometry setup using a well calibrated hyper pure germanium cylindrical detector. The theoretical values of the mass attenuation coefficients were evaluated using the XCOM program database. The experimental results demonstrated that, according to the filler size, cadmium oxide composite is better as a gamma absorber in the energy region less than 81 keV, while lead oxide composite is better in the energy region greater than 81 keV. Moreover, for the same chemical structure and weight fraction of the composite, nano fillers show better attenuation performance than micro fillers in high density polyethylene based radiation shielding material. nema
AbstractList	In this work, polymer composites of high density polyethylene reinforced by micro-sized and nanosized cadmium oxide, lead oxide, and a mixture of both with filler weight fraction of 30% were prepared by compression molding technique and characterized by scanning electron microscope. This investigation aims to present a comparative study between cadmium oxide and lead oxide according to their sizes as fillers in high density polyethylene polymeric matrix for gamma-radiation shielding applications. The mass and linear attenuation coefficients of the investigated composites were measured as a function of g-ray energies ranging from 59.53 keV to 1408.01 keV using standard radioactive point sources (241Am, 133Ba, 137Cs, 60Co, and 152Eu). The measurements were made with a narrow beam geometry setup using a well calibrated hyper pure germanium cylindrical detector. The theoretical values of the mass attenuation coefficients were evaluated using the XCOM program database. The experimental results demonstrated that, according to the filler size, cadmium oxide composite is better as a gamma absorber in the energy region less than 81 keV, while lead oxide composite is better in the energy region greater than 81 keV. Moreover, for the same chemical structure and weight fraction of the composite, nano fillers show better attenuation performance than micro fillers in high density polyethylene based radiation shielding material. In this work, polymer composites of high density polyethylene reinforced by micro-sized and nanosized cadmium oxide, lead oxide, and a mixture of both with filler weight fraction of 30% were prepared by compression molding technique and characterized by scanning electron microscope. This investigation aims to present a comparative study between cadmium oxide and lead oxide according to their sizes as fillers in high density polyethylene polymeric matrix for gamma-radiation shielding applications. The mass and linear attenuation coefficients of the investigated composites were measured as a function of g-ray energies ranging from 59.53 keV to 1408.01 keV using standard radioactive point sources (241Am, 133Ba, 137Cs, 60Co, and 152Eu). The measurements were made with a narrow beam geometry setup using a well calibrated hyper pure germanium cylindrical detector. The theoretical values of the mass attenuation coefficients were evaluated using the XCOM program database. The experimental results demonstrated that, according to the filler size, cadmium oxide composite is better as a gamma absorber in the energy region less than 81 keV, while lead oxide composite is better in the energy region greater than 81 keV. Moreover, for the same chemical structure and weight fraction of the composite, nano fillers show better attenuation performance than micro fillers in high density polyethylene based radiation shielding material. nema
Author	Aloraini, Dalal El-Khatib, Ahmed Alabsy, Mahmoud Abbas, Mahmoud Elzaher, Mohamed Alharshan, Gharam Badawi, Mohamed
Author_xml	– sequence: 1 givenname: Gharam surname: Alharshan fullname: Alharshan, Gharam organization: Physics Department, Faculty of Science, Princess Nourah Bint Abdulrahaman University, Riyadh, Saudi Arabia – sequence: 2 givenname: Dalal surname: Aloraini fullname: Aloraini, Dalal organization: Physics Department, Faculty of Science, Princess Nourah Bint Abdulrahaman University, Riyadh, Saudi Arabia – sequence: 3 givenname: Mohamed surname: Elzaher fullname: Elzaher, Mohamed organization: Department of Basic and Applied Science, Faculty of Engineering, Arab Academy for Science and Technology, Alexandria, Egypt – sequence: 4 givenname: Mohamed surname: Badawi fullname: Badawi, Mohamed organization: Department of Physics, Faculty of Science, Beirut Arab University, Beirut, Lebanon – sequence: 5 givenname: Mahmoud surname: Alabsy fullname: Alabsy, Mahmoud organization: Physics Department, Faculty of Science, Alexandria University, Alexandria, Egypt – sequence: 6 givenname: Mahmoud surname: Abbas fullname: Abbas, Mahmoud organization: Physics Department, Faculty of Science, Alexandria University, Alexandria, Egypt – sequence: 7 givenname: Ahmed surname: El-Khatib fullname: El-Khatib, Ahmed organization: Physics Department, Faculty of Science, Alexandria University, Alexandria, Egypt
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SubjectTerms	Attenuation coefficients Cadmium Cesium 137 Cesium isotopes Comparative studies Fillers gamma radiation shielding Gamma rays Germanium high density polyethylene composites High density polyethylenes Lead oxides linear attenuation coefficient Mathematical analysis nano-cadmium oxide nano-lead oxide Point sources Polyethylene Polymer matrix composites Pressure molding Radiation shielding Weight
Title	A comparative study between nano-cadmium oxide and lead oxide reinforced in high density polyethylene as gamma rays shielding composites
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