A study on radiation shielding potentials of green and red clayey soils in Turkey reinforced with marble dust and waste tire

Year 2021, Volume: 10 Issue: 3, 46 - 59, 31.12.2021

Zeynep Aygun Murat Aygün Necmi Yarbaşı

https://doi.org/10.54187/jnrs.986038

Cited By: 4

Abstract

The increasing radiation applications in our daily life makes it essential to protect ourselves from the harms of radiation by using alternative, cheap and natural materials. The present study aimed to analyze the radiation shielding abilities of green and red clayey soils from Oltu/Erzurum in Turkey, reinforced with waste tires and marble dust. For the purpose to investigate the shielding features of the samples, radiation attenuation parameters were determined by using EpiXS software, which can calculate partial or total cross-sections, partial or total mass attenuation coefficients, electron densities, effective atomic numbers, and buildup factors for energy absorption and exposure between 1keV and 1GeV. We compared the obtained mass attenuation coefficients and total atomic cross-section values of the samples with those of a widely used shielding material, ordinary concrete, to make a meaningful evaluation about the shielding potentials of the samples. To validate obtained values by EpiXS, we also calculated the mass attenuation coefficients of the samples by XCOM code, and compatible results were obtained. Among all the studied clayey soil samples, green clay reinforced with marble dust and waste tire has the highest shielding capability. It can also be mentioned that reinforcement with marble dust and waste tire improves the shielding ability of the clayey soils.

Keywords

Green and red clayey soil, EpiXS, Radiation shielding, Marble dust, Waste tire

References

• Z. Aygun, N. Yarbasi, A Spectroscopic Analysis of Clay Types and Silty Sand from Oltu/Erzurum (Turkey) Region Reinforcing with Marble Dust and Waste Tire, Karaelmas Science and Engineering Journal, 9(2), (2019) 215-226.
• M. Jafari, M. Esnaashari, Effect of waste tire cord reinforcement on unconfined compressive strength of lime stabilized clayey soil under freeze-thaw condition, Cold Regions Science and Technology, 82, (2012) 21-29.
• R. T. Erdem, A. U. Oztürk, Effect of Marble Powder Additive on Freezing-Thawing Properties of Cement Mortar, BEU Journal of Science, 1(2), (2012) 85-91.
• N. Yarbasi, E. Kalkan, The Mechanical Performance of Clayey Soils Reinforced with Waste PET Fibers, International Journal of Earth Science and Knowledge Applications, 2(1), (2020) 19-26.
• B. Aygün, Neutron and gamma radiation shielding properties of high-temperature-resistant heavy concretes including chromite and wolframite, Journal of Radiation Research and Applied Sciences, 12, (2019) 352-359.
• R. S. M. Rashid, S. M. Salem, N. M. Azreen, Y. L. Voo, M. Haniza, A. A. Shukri, M. S. Yahya, Effect of elevated temperature to radiation shielding of ultra-high-performance concrete with silica sand or magnetite, Construction and Building Materials, 262, (2020) 120567
• O. Gencel, A. Bozkurt, E. Kam, T. Korkut, Determination and calculation of gamma and neutron shielding characteristics of concretes containing different hematite proportions, Annals of Nuclear Energy, 38, (2011) 2719–2723.
• Gür, B. Artıg, T. Cakır, Photon attenuation properties of concretes containing magnetite and limonite ores, Physicochemical Problems of Mineral Process, 53(1), (2017) 184−191.
• Akkurt, H. Canakci, Radiation attenuation of boron-doped clay for 662, 1173 and 1332 keV gamma rays, Iranian Journal of Radiation Research, 9(1), (2011) 37-40.
• H. S. Mann, G. S. Brar, G. S. Mudahar, Gamma-ray shielding effectiveness of novel light-weight clay-flyash bricks, Radiation Physics and Chemistry, 127, (2016) 97-101.
• S. F. Olukotun, S. T. Gbenu, F. I. Ibitoye, O. F. Oladejo, H. O. Shittu, M. K. Fasasi, F. A. Balogun, Investigation of gamma radiation shielding capability of two clay materials, Nuclear Engineering and Technology, 50, (2018) 957-962.
• M. J. Berger, J. H. Hubbell, XCOM: Photon Cross Sections Database, Web Version 1.2. National Institute of Standards and Technology Gaithersburg, MD, (1987) 20899, USA, available at. http://physics.nist.gov/xcom.
• S. Agostinelli, J. Allison, K. Amako, J. Apostolakis, H. Araujo, et al., Geant4-a simulation toolkit, Nuclear Instrumentation and Methods Physics Research Section A, 506, (2003) 250-303.
• L. Gerward, N. Guilbert, K. B. Jensen, H. Levring, X-ray absorption in matter. Reengineering XCOM, Radiation Physics and Chemistry, 60, (2001) 23–24.
• L. Gerward, N. Guilbert, K. B. Jensen, H. Levring, WinXCom-a program for calculating X-ray attenuation coefficients, Radiation Physics and Chemistry, 71, (2004) 653–654.
• R. Nowotny, XMuDat: Photon attenuation data on PC, IAEA Report IAEA-NDS, (1998) 195.
• E. Sakar, Ö. F. Özpolat, B. Alım, M.I. Sayyed, M. Kurudirek, Phy-X / PSD: Development of a user friendly online software for calculation of parameters relevant to radiation shielding and dosimetry, Radiation Physics and Chemistry, 166, (2020) 1-12.
• S. Mann, S. S. Mann, Py-MLBUF: Development of an online-platform for gamma-ray shielding calculations and investigations, Annals of Nuclear Energy, 150, (2021) 107845.
• F. C. Hila, A. A. Astronomo, C. A. M. Dingle, J. F. M. Jecong, A. M. V. Javier-Hila, et al., EpiXS: A Windows-based program for photon attenuation, dosimetry and shielding based on EPICS2017 (ENDF/B-VIII) and EPDL97 (ENDF/B-VI8), Radiation Physics and Chemistry, 182, (2021) 109331.
• Z. Aygun, M. Aygun, A study on usability of Ahlat ignimbrites and pumice as radiation shielding materials, by using EpiXS code, International Journal of Environmental Science and Technology, (2021). https://doi.org/10.1007/s13762-021-03530-9.
• M. B. Z. Gili, F. C. Hila, Investigation of Gamma-ray Shielding Features of Several Clay Materials Using the EPICS2017 Library, Philippine Journal of Science, 150 (5), (2021) 1017-1026.
• Z. Aygun, N. Yarbasi, M. Aygun Spectroscopic and radiation shielding features of Nemrut, Pasinler, Sarıkamıs and Ikizdere obsidians in Turkey: Experimental and theoretical study, Ceramics International, (2021). https://doi.org/10.1016/j.ceramint.2021.08.330.
• H. Almuqrin, M. I. Sayyed, J. F. M. Jecong, A. Kumar, M. M. AlShammari, B. Albarzan, SrO-SiO2-B2O3-ZrO2 glass system: Effects of varying SrO and BaO compositions to physical and optical properties, and radiation shielding using EPDL2017 photoatomic library, Optik, 245, (2021) 167670.
• N. Yarbasi, Geotechnical mapping of Oltu (Erzurum) residential area and its vicinity, Pamukkale University Journal of Engineering and Science, 22, (2016) 538-545.
• D. F. Jackson, D.J. Hawkes, X-ray attenuation coefficients of elements and mixtures, Physics Reports, 70, (1981) 169–233.
• F. Pires, Soil analysis using nuclear techniques: a literature review of the gamma ray attenuation method, Soil Tillage Research, 184, (2018) 216–234.
• S. Prabhu, A. C. Sneha, P. P. Shetty, A. A. Narkar, S. G. Bubbly, S. B. Gudennavar, Effective atomic number and electron density of some biologically important lipids for electron, proton, alpha particle and photon interactions, Applied Radiation and Isotopes, 160, (2020) 109137.
• Y. Harima, An historical review and current status of buildup factor calculations and applications, Radiation Physics and Chemistry, 41(4–5), (1993) 631–672.
• Y. Harima, Y. Sakamoto, S. Tanaka, M. Kawai, Validity of the geometric-progression formula in approximating gamma-ray buildup factors, Nuclear Science and Engineering, 94(1), (1986) 24–35.
• ANSI/ANS 643, Gamma-ray Attenuation Coefficients and Buildup Factors for Engineering Materials, American Nuclear Society La Grange Park Illinois (1991).
• I. Bashter, Calculation of radiation attenuation coefficients for shielding concretes, Annals of Nuclear Energy, 24(17), (1997) 1389-1401.
• N. Kücük, O. Gezer, Determination of Build-up Factors for Natural Black Obsidian Ores, AKU Journal of Science and Engineering, 17, (2017) 872-880.
• S. S. Obaid, M. I. Sayyed, D. K. Gaikwad, P. P. Pawara, Attenuation coefficients and exposure buildup factor of some rocks for gamma ray shielding applications, Radiation Physics and Chemistry, 148, (2018) 86-94.