The impact of B2O3/Al2O3 substitution on physical properties and γ-ray shielding competence of aluminum-borate glasses: comparative study

This work investigates the impact of B 2 O 3 /Al 2 O 3 substitution on the physical properties and γ-ray shielding parameters in the γ-energy range of 0.015: 15 MeV of the aluminum-borate glasses with the composition: (75-X)B 2 O 3 + 10ZnO + 10CdO + 5Na 2 O + XAl 2 O 3 where X = 5 (BNCZAl-5)–20 (BN...

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Published in	Journal of materials science. Materials in electronics Vol. 35; no. 12; p. 845
Main Authors	Abouhaswa, A. S., Abdelghany, A. M., Alfryyan, Nada, Alsaif, Norah A. M., Rammah, Y. S., Nabil, Islam M.
Format	Journal Article
Language	English
Published	New York Springer US 01.04.2024 Springer Nature B.V
Subjects	Aluminum Aluminum oxide Attenuation coefficients Boron oxides Characterization and Evaluation of Materials Chemistry and Materials Science Comparative studies Gamma rays Materials Science Molar volume Optical and Electronic Materials Oxygen Packing density Physical properties Radiation shielding Substitutes
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Abstract	This work investigates the impact of B 2 O 3 /Al 2 O 3 substitution on the physical properties and γ-ray shielding parameters in the γ-energy range of 0.015: 15 MeV of the aluminum-borate glasses with the composition: (75-X)B 2 O 3 + 10ZnO + 10CdO + 5Na 2 O + XAl 2 O 3 where X = 5 (BNCZAl-5)–20 (BNCZAl-20)% mol (with step of 5%). Samples were fabricated using the well-known melt quenching technique. The density (ρ) increased gradually from 3.492 to 3.901 g/cm 3 and molar volume (V m ) decreased from 22.311 to 21.216 cm 3 /mol as the Al 2 O 3 content increased from 5 to 20 mol%. The oxygen molar volume (OMV) increased from 9.107 to 9.868 cm 3 /mol, while the oxygen packing density (OPD) values decreased from 109.810 to 101.341 g.atom/l. Linear-attenuation coefficient (μ) followed the order: BNCZAl-5 < BNCZAl-10 < BNCZAl-15 < BNCZAl-20. The sample that coded as BNCZAL-20 (highest content of Al 2 O 3 ) possessed the lowest half-value (HVL) and tenth-value (TVL) layers among all studied samples. Within the investigated energy range of Zef Z ef within the range: from 27.324 to 10.783, 26.820 to 10.957, 26.351 to 11.128, and 25.915 to 11.296 for the prepared samples BNCZAl-5, BNCZAl-10, BNCZAl-15, and BNCZAl-20 glasses, respectively. The obtained results confirmed that the suggested glasses can be used as alternative materials for radiation shielding applications.
AbstractList	This work investigates the impact of B2O3/Al2O3 substitution on the physical properties and γ-ray shielding parameters in the γ-energy range of 0.015: 15 MeV of the aluminum-borate glasses with the composition: (75-X)B2O3 + 10ZnO + 10CdO + 5Na2O + XAl2O3 where X = 5 (BNCZAl-5)–20 (BNCZAl-20)% mol (with step of 5%). Samples were fabricated using the well-known melt quenching technique. The density (ρ) increased gradually from 3.492 to 3.901 g/cm3 and molar volume (Vm) decreased from 22.311 to 21.216 cm3/mol as the Al2O3 content increased from 5 to 20 mol%. The oxygen molar volume (OMV) increased from 9.107 to 9.868 cm3/mol, while the oxygen packing density (OPD) values decreased from 109.810 to 101.341 g.atom/l. Linear-attenuation coefficient (μ) followed the order: BNCZAl-5 < BNCZAl-10 < BNCZAl-15 < BNCZAl-20. The sample that coded as BNCZAL-20 (highest content of Al2O3) possessed the lowest half-value (HVL) and tenth-value (TVL) layers among all studied samples. Within the investigated energy range of ZefZef within the range: from 27.324 to 10.783, 26.820 to 10.957, 26.351 to 11.128, and 25.915 to 11.296 for the prepared samples BNCZAl-5, BNCZAl-10, BNCZAl-15, and BNCZAl-20 glasses, respectively. The obtained results confirmed that the suggested glasses can be used as alternative materials for radiation shielding applications. This work investigates the impact of B 2 O 3 /Al 2 O 3 substitution on the physical properties and γ-ray shielding parameters in the γ-energy range of 0.015: 15 MeV of the aluminum-borate glasses with the composition: (75-X)B 2 O 3 + 10ZnO + 10CdO + 5Na 2 O + XAl 2 O 3 where X = 5 (BNCZAl-5)–20 (BNCZAl-20)% mol (with step of 5%). Samples were fabricated using the well-known melt quenching technique. The density (ρ) increased gradually from 3.492 to 3.901 g/cm 3 and molar volume (V m ) decreased from 22.311 to 21.216 cm 3 /mol as the Al 2 O 3 content increased from 5 to 20 mol%. The oxygen molar volume (OMV) increased from 9.107 to 9.868 cm 3 /mol, while the oxygen packing density (OPD) values decreased from 109.810 to 101.341 g.atom/l. Linear-attenuation coefficient (μ) followed the order: BNCZAl-5 < BNCZAl-10 < BNCZAl-15 < BNCZAl-20. The sample that coded as BNCZAL-20 (highest content of Al 2 O 3 ) possessed the lowest half-value (HVL) and tenth-value (TVL) layers among all studied samples. Within the investigated energy range of Zef Z ef within the range: from 27.324 to 10.783, 26.820 to 10.957, 26.351 to 11.128, and 25.915 to 11.296 for the prepared samples BNCZAl-5, BNCZAl-10, BNCZAl-15, and BNCZAl-20 glasses, respectively. The obtained results confirmed that the suggested glasses can be used as alternative materials for radiation shielding applications.
ArticleNumber	845
Author	Abouhaswa, A. S. Abdelghany, A. M. Nabil, Islam M. Alfryyan, Nada Rammah, Y. S. Alsaif, Norah A. M.
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Snippet	This work investigates the impact of B 2 O 3 /Al 2 O 3 substitution on the physical properties and γ-ray shielding parameters in the γ-energy range of 0.015:... This work investigates the impact of B2O3/Al2O3 substitution on the physical properties and γ-ray shielding parameters in the γ-energy range of 0.015: 15 MeV...
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SubjectTerms	Aluminum Aluminum oxide Attenuation coefficients Boron oxides Characterization and Evaluation of Materials Chemistry and Materials Science Comparative studies Gamma rays Materials Science Molar volume Optical and Electronic Materials Oxygen Packing density Physical properties Radiation shielding Substitutes
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Title	The impact of B2O3/Al2O3 substitution on physical properties and γ-ray shielding competence of aluminum-borate glasses: comparative study
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