Determination of Transmission Factors and γ-Ray Linear Attenuation Coefficients of Some Construction Materials Mixed with Ulexite and Borax

Salih Zeki Erzeneoğlu; Burcu Akça; Hidayet Uyanık

doi:10.17776/csj.1338905

Araştırma Makalesi

Determination of Transmission Factors and γ-Ray Linear Attenuation Coefficients of Some Construction Materials Mixed with Ulexite and Borax

Yıl 2024, , 379 - 385, 30.06.2024

Salih Zeki Erzeneoğlu , Burcu Akça , Hidayet Uyanık

https://doi.org/10.17776/csj.1338905

Öz

In the study, transmission factors (T) and linear attenuation coefficients (μ) of some construction materials (briquette, sand, marble, paint, adobe, soil, and lime) mixed with ulexite and borax are measured with energy dispersive X-ray fluorescence spectrometer for 59.5 keV energy by using a Si(Li) detector. Ulexite and borax were added to the samples at a rate of 25, 50, and 75 percent. Results are presented and discussed in this paper. Measurements made on these construction materials with technological importance will create new use areas

Anahtar Kelimeler

Construction material, Radiation isolation, EDXRFS

Teşekkür

The authors are thankful to ETİMADEN for the sample.

Kaynakça

[1] Mhareb M. H. A., Mostafa Z., Mohamed E., Alajerami Y. S., Sayyed M. I., Gameel S., Hamad R. M., Hamad M. Kh., Radiation Shielding Features for Various Telluriumbased Alloys: a Comparative Study, J Mater Sci: Mater Electron, 32 (2021) 26798– 26811.
[2] Zayed A.M., Masoud M.A., Shahien M.G., Gökçe H.S., Sakr K., Kansouh W.A., El-Khayatt A.M., Physical, Mechanical and Radiation Attenuation Properties of Serpentine Concrete Containing Boric Acid, Construction and Building Materials, 272 (2021) 121641.
[3] Zahran H.Y., El Sayed Y., Yahia I.S., Novel approach of gamma attenuation performance of Cu2SnZn(S, Se, Te)4 semiconductor materials: Radiation interactions with proton, alpha, carbon, electron, and photon, Materials Science in Semiconductor Processing, 123 (2021), 105554.
[4] Milad A., Salar H. G., Mohammad H. N., Kazem J., Zohre M., Ali J., Peyman I., Ali M. A., Mesoporous Silica Nanoparticle: Heralding a Brighter Future in Cancer Nanomedicine, Microporous and Mesoporous Materials, 319 (2021) 110967.
[5] Anugrah M. A., Ilyas S., Tahir D., Gelatin/Poly (vinyl alcohol) / Inorganic Filler Composites for Phantom Breasts, Materials Chemistry and Physics, 262 (2021) 124333.
[6] Kumar A. M., Manjula G., Nageshwar Rao A.S., Measurement of mass attenuation coefficient of ZIRCONIUM (Zr), Zirconium Chloride (ZrCl4) and Zirconium Silicate (ZrSiO4) near the K-edge using synchrotron Radiation, Materials Today: Proceedings, 38 (2021) 2927–2934.
[7] Akça B., Gürbulak B., Erzeneoğlu S. Z., Effect of Voltages on γ-Ray Linear Attenuation Coefficients for Some Semiconductors, Radiation Physics and Chemistry, 179 (2021) 109208.
[8] [8] Saleh E. E., Mohammed A. K., Elmonem El-Fiki S.A., Radiological and Gamma-ray Shielding Parameters of Cement Raw Materials Samples Used in Yemen, Eur. Phys. J. Plus, 136 (2021) 890.
[9] [9] Tyagi G., Singhal A., Routroy S., Bhunia D., Lahoti M., Radiation Shielding Concrete with alternate constituents: An approach to address multiple hazards,, Journal of Hazardous Materials 404 (2021) 124201.
[10] Akça B., Erzeneoğlu S. Z., The Mass Attenuation Coefficients, Electronic, Atomic, and Molecular Cross Sections, Effective Atomic Numbers, and Electron Densities for Compounds of Some Biomedically Important Elements at 59.5 keV, Science and Technology of Nuclear Installations, (2014) 8 pag.
[11] Böke A., Linear attenuation coefficients of tissues from 1 keV to 150 keV, Radiation Physics and Chemistry, 102 (2014) 49-59.
[12] Akça B., Ulusoy Ö., Erzeneoğlu S. Z., Total Mass Attenuation Coefficients, Total Photon Interaction Cross Sections, Effective Atomic Numbers and Effective Electron Densities for Some Construction Materials Available in Turkey, Arabian Journal for Science and Engineering 6(2022) (2021).
[13] Madej D., Silarski M., Parzych S., Design, Structure, Microstructure and Gamma Radiation Shielding Properties of Refractory Concrete Materials Containing Ba- and Sr-doped Cements, Materials Chemistry and Physics 260 (2021) 124095.
[14] Eke C., Investigation of Gamma-ray Attenuation Properties of Beach Sand Samples from Antalya, Turkey, Arabian Journal of Geosciences 14(159), (2021).
[15] Erzeneoğlu S., İçelli O., Gürbulak B., Ateş A., Measurement of Mass Attenuation Coefficients for Holmium Doped and Undoped Layered Semiconductors InSe at Different Energies and The Validity of Mixture Rule for Crystals Around The Absorption Edge, Journal of Quantitative Spectroscopy & Radiative Transfer, 102 (2006) 343–347.
[16] Samson D. O., Shukri A., Jafri M. Z. M., Hashim R., Sulaiman O., Abdul Aziz M. Z., Yusof M. F. M., Characterization of Rhizophora SPP. Particleboards with SOY Protein Isolate Modified with NaOH/IA-PAE Adhesive for Use as Phantom Material at Photon Energies of 16.59e25.26 keV, Nuclear Engineering and Technology 53 (2021) 216-233.
[17] Koirala B., Dhobin S. H., Khadka D., Yadav K., Nakarmi J. J., Poudyal K., Study The Radiation Shielding Material of Iron Oxides on the Basis of Total Cross Section, IOSR Journal of Applied Physics (IOSR-JAP), 13(6) (2021) 19-25.
[18] Cinan E., Yılmaz D., Effective Atomic Numbers of Boron Compounds Obtained using Rayleigh to Compton Scattering Intensity Ratio, Applied Radiation and Isotopes 174 (2021) 109753.
[19] Kurudirek M., Aygün M., Erzeneoğlu S., Chemical Composition, Effective Atomic Number and Electron Density Study of Trommel Sieve Waste (TSW), Portland Cement, Lime, Pointing and Their Admixtures with TSW in Different Proportions, Applied Radiation and Isotopes, 68(6) (2010) 1006-1011.
[20] Gökmen U., Gamma and Neutron Shielding Properties of B4C Particle Reinforced Inconel 718 Composites, Nuclear Engineering and Technology, 54(3) (2022) 1049-1061.

Yıl 2024, , 379 - 385, 30.06.2024

Salih Zeki Erzeneoğlu , Burcu Akça , Hidayet Uyanık

https://doi.org/10.17776/csj.1338905

Öz

Kaynakça

[1] Mhareb M. H. A., Mostafa Z., Mohamed E., Alajerami Y. S., Sayyed M. I., Gameel S., Hamad R. M., Hamad M. Kh., Radiation Shielding Features for Various Telluriumbased Alloys: a Comparative Study, J Mater Sci: Mater Electron, 32 (2021) 26798– 26811.
[2] Zayed A.M., Masoud M.A., Shahien M.G., Gökçe H.S., Sakr K., Kansouh W.A., El-Khayatt A.M., Physical, Mechanical and Radiation Attenuation Properties of Serpentine Concrete Containing Boric Acid, Construction and Building Materials, 272 (2021) 121641.
[3] Zahran H.Y., El Sayed Y., Yahia I.S., Novel approach of gamma attenuation performance of Cu2SnZn(S, Se, Te)4 semiconductor materials: Radiation interactions with proton, alpha, carbon, electron, and photon, Materials Science in Semiconductor Processing, 123 (2021), 105554.
[4] Milad A., Salar H. G., Mohammad H. N., Kazem J., Zohre M., Ali J., Peyman I., Ali M. A., Mesoporous Silica Nanoparticle: Heralding a Brighter Future in Cancer Nanomedicine, Microporous and Mesoporous Materials, 319 (2021) 110967.
[5] Anugrah M. A., Ilyas S., Tahir D., Gelatin/Poly (vinyl alcohol) / Inorganic Filler Composites for Phantom Breasts, Materials Chemistry and Physics, 262 (2021) 124333.
[6] Kumar A. M., Manjula G., Nageshwar Rao A.S., Measurement of mass attenuation coefficient of ZIRCONIUM (Zr), Zirconium Chloride (ZrCl4) and Zirconium Silicate (ZrSiO4) near the K-edge using synchrotron Radiation, Materials Today: Proceedings, 38 (2021) 2927–2934.
[7] Akça B., Gürbulak B., Erzeneoğlu S. Z., Effect of Voltages on γ-Ray Linear Attenuation Coefficients for Some Semiconductors, Radiation Physics and Chemistry, 179 (2021) 109208.
[8] [8] Saleh E. E., Mohammed A. K., Elmonem El-Fiki S.A., Radiological and Gamma-ray Shielding Parameters of Cement Raw Materials Samples Used in Yemen, Eur. Phys. J. Plus, 136 (2021) 890.
[9] [9] Tyagi G., Singhal A., Routroy S., Bhunia D., Lahoti M., Radiation Shielding Concrete with alternate constituents: An approach to address multiple hazards,, Journal of Hazardous Materials 404 (2021) 124201.
[10] Akça B., Erzeneoğlu S. Z., The Mass Attenuation Coefficients, Electronic, Atomic, and Molecular Cross Sections, Effective Atomic Numbers, and Electron Densities for Compounds of Some Biomedically Important Elements at 59.5 keV, Science and Technology of Nuclear Installations, (2014) 8 pag.
[11] Böke A., Linear attenuation coefficients of tissues from 1 keV to 150 keV, Radiation Physics and Chemistry, 102 (2014) 49-59.
[12] Akça B., Ulusoy Ö., Erzeneoğlu S. Z., Total Mass Attenuation Coefficients, Total Photon Interaction Cross Sections, Effective Atomic Numbers and Effective Electron Densities for Some Construction Materials Available in Turkey, Arabian Journal for Science and Engineering 6(2022) (2021).
[13] Madej D., Silarski M., Parzych S., Design, Structure, Microstructure and Gamma Radiation Shielding Properties of Refractory Concrete Materials Containing Ba- and Sr-doped Cements, Materials Chemistry and Physics 260 (2021) 124095.
[14] Eke C., Investigation of Gamma-ray Attenuation Properties of Beach Sand Samples from Antalya, Turkey, Arabian Journal of Geosciences 14(159), (2021).
[15] Erzeneoğlu S., İçelli O., Gürbulak B., Ateş A., Measurement of Mass Attenuation Coefficients for Holmium Doped and Undoped Layered Semiconductors InSe at Different Energies and The Validity of Mixture Rule for Crystals Around The Absorption Edge, Journal of Quantitative Spectroscopy & Radiative Transfer, 102 (2006) 343–347.
[16] Samson D. O., Shukri A., Jafri M. Z. M., Hashim R., Sulaiman O., Abdul Aziz M. Z., Yusof M. F. M., Characterization of Rhizophora SPP. Particleboards with SOY Protein Isolate Modified with NaOH/IA-PAE Adhesive for Use as Phantom Material at Photon Energies of 16.59e25.26 keV, Nuclear Engineering and Technology 53 (2021) 216-233.
[17] Koirala B., Dhobin S. H., Khadka D., Yadav K., Nakarmi J. J., Poudyal K., Study The Radiation Shielding Material of Iron Oxides on the Basis of Total Cross Section, IOSR Journal of Applied Physics (IOSR-JAP), 13(6) (2021) 19-25.
[18] Cinan E., Yılmaz D., Effective Atomic Numbers of Boron Compounds Obtained using Rayleigh to Compton Scattering Intensity Ratio, Applied Radiation and Isotopes 174 (2021) 109753.
[19] Kurudirek M., Aygün M., Erzeneoğlu S., Chemical Composition, Effective Atomic Number and Electron Density Study of Trommel Sieve Waste (TSW), Portland Cement, Lime, Pointing and Their Admixtures with TSW in Different Proportions, Applied Radiation and Isotopes, 68(6) (2010) 1006-1011.
[20] Gökmen U., Gamma and Neutron Shielding Properties of B4C Particle Reinforced Inconel 718 Composites, Nuclear Engineering and Technology, 54(3) (2022) 1049-1061.

Toplam 20 adet kaynakça vardır.

Ayrıntılar

Birincil Dil	İngilizce
Konular	Atom ve Molekül Fiziği
Bölüm	Natural Sciences
Yazarlar	Salih Zeki Erzeneoğlu 0000-0002-0890-6099 Burcu Akça 0000-0003-2399-5971 Hidayet Uyanık 0009-0003-2014-567X
Yayımlanma Tarihi	30 Haziran 2024
Gönderilme Tarihi	7 Ağustos 2023
Kabul Tarihi	18 Nisan 2024
Yayımlandığı Sayı	Yıl 2024

Kaynak Göster

APA	Erzeneoğlu, S. Z., Akça, B., & Uyanık, H. (2024). Determination of Transmission Factors and γ-Ray Linear Attenuation Coefficients of Some Construction Materials Mixed with Ulexite and Borax. Cumhuriyet Science Journal, 45(2), 379-385. https://doi.org/10.17776/csj.1338905

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