Assessment of Natural Radioactivity Levels and Radiation Hazards for Soil Samples Used in Erbil Governorate, Iraqi Kurdistan

Zakariya A. Hussein

doi:10.14500/aro.10471

Zakariya A. Hussein Department of Physics, Faculty of Sciences and Health, Koya University, Koya KOY45, Kurdistan Region http://orcid.org/0000-0001-8120-6550

Keywords: Gamma Ray Spectroscopy, Radioactivity, Soil, Erbil governorate

Abstract

In this work, the activity concentrations of natural radionuclides ²²⁶Ra, ²³²Th and ⁴⁰K in soil samples from Erbil governorate, Iraqi Kurdistan were investigated by a gamma-spectroscopy system based on high-purity germanium (HPGe) detector. This is to assess the dose of radionuclides exposure to the population, knowing the health risks and to have a baseline for future changes in the environmental radioactivity. It was found that the activity concentrations of ²²⁶Ra, ²³²Th and ⁴⁰K were ranged from (14.6 ± 1.6 to 38.2 ± 2.8 Bq.kg^-1), (4.5 ± 1.4 to 52.4 ± 5.8 Bq.kg^-1) and ( 302.8 ± 12.6 to 388.6 ± 12.8 Bq.kg^-1), respectively. The measured activity concentrations for these radionuclides were compared with the reported data of other countries and with the worldwide average activity of soil. Radium equivalent activities, absorbed dose rate, excess lifetime cancer risk and the values of hazard indices were calculated for the measured samples to assess the radiation hazard of the natural radioactivity in all samples to the people. It was concluded that the radium equivalent activities of the studied samples are below the internationally accepted values. These results show that annual effective dose absorbed via occupant from activity construction of soil samples used in the under place is below 1.0 mSv.y^-1. It is concluded that the assessment radioactivity of soil are within acceptable levels and does not pose any health hazard to the population.

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Author Biography

Zakariya A. Hussein, Department of Physics, Faculty of Sciences and Health, Koya University, Koya KOY45, Kurdistan Region

Zakariya A. Hussein is an Assistance Prof. at the Department of Physics, Faculty of Science and Health, Koya University. He got his Ph.D. degree in Radiation and Medical Physics. His research interests are: .Radiation, Biophysics, Medical Physics, Environment and Radioactivity.

References

Ahmed, A.H., and Samad, A.I., 2014. Measurement of radioactivity levels in daily intake foods of Erbil city inhabitants. Journal of Zankoy Sulaimani Part A, 16(4), pp.111-121.

Ali, M.M., 2011. Measurement of radon-222 concentration in soil samples of some sulfuric spring in hit city using CR-39 detector. Baghdad Science Journal, 8(4), pp.972-975.

AL-Zahrani, J.H., 2012. Natural radioactivity and heavy metals in milk consumed in Saudi Arabia and population dose rate estimates. Life Science Journal, 9(2), pp.651-656.

Alzubaidi, G., Hamid, F.B., and Abdul, R.I., 2016. Assessment of natural radioactivity levels and radiation hazards in agricultural and virgin soil in the state of Kedah, North of Malaysia. The Scientific World Journal, 2016, p.9.

Amrani, D., and Tahtat, M., 2001. Natural radioactivity in Algerian building materials. Applied Radiation and Isotopes, 54, pp.687-689.

Azeez, H.H., Ahmad, S.T., and Hanna, H., 2018. Assessment of radioactivity levels and radiological-hazard indices in plant fertilizers used in Iraqi Kurdistan region. Journal of Radioanalytical and Nuclear Chemistry, 317, pp.1273-1283.

Aziz, A.Q., Ishtiaq, A.K., Jadoon, A.A., Wajid, A.A., Adil, M.M., Anees, S.M., Abdul, W., and Aneela, T., 2014. Study of natural radioactivity in Mansehra granite, Pakistan: Environmental concerns. Radiation Protection Dosimetry, 158(4), pp.466-478.

Darwish, D.A.E., Abul-Nasr, K.T.M., and El-Khayatt, A.M., 2015. The assessment of natural radioactivity and its associated radiological hazards and dose parameters in granite samples from South Sinai, Egypt. Journal of Radiation Research and Applied Sciences, 8(1), pp.17-25.

Dashty, T.A., and Ali, H.A., 2013. Measurement of radioactivity for 226Ra radionuclide in soil samples from Bekhma region using gamma ray spectrometry. Journal of Concepts in Pure and Applied Science, 1(1), pp.44-48.

Eissa, H.S., Medhat, M.E., Said, S.A., and Elmaghraby, E.K., 2010. Radiation dose estimation of sand samples collected from different Egyptian beaches. Radiation Protection Dosimetry, 147, pp.533-540.

EL-Taher, A., and Abdelhal, M.A.K., 2013. Elemental analysis of phosphate fertilizer consumed in Saudi Arabia. Life Science Journal, 10(4), pp.701-708.

Fasae, K.P., 2013. Natural radioactivity in locally produced building materials in Ekiti state, Southwestern Nigeria. Civil and Environmental Research, 3(11), pp.99-112.

Goddard, C.C., 2002. Measurement of outdoor terrestrial gamma radiation in the Sultanate of Oman. Health Physics, 82(6), pp.869-874.

Hammood, H.A., and Al-Khalifa, I.J.M., 2011. Radon concentration measurement in water of Dhi-Qar governorate in Iraq using emanometer. Journal of Basrah Researches (Sciences), 37(5), pp.22-29.

Hassan, N.M., Mansour, N.A., and Hassan, M.F., 2013. Evaluation of radionuclides concentration and association radiological hazard indexes in building materials used in Egypt. Radiation Protection Dosimetry, 157, pp.214-220.

Hussain, R.O., and Abbas, E.K., 2010. Measurement of natural occurring radio nuclides (NORMs) in soil using gamma- ray spectrometry. Journal of Kufa Physics, 2(2), pp.15-22.

Hussain, R.O., and Hussain, H.H., 2011. Investigation the natural radioactivity in local and imported chemical fertilizers. Brazilian Archives of Biology and Technology, 54(4), pp.777-782.

Hussein, A., 2011. Successive uranium and thorium adsorption from Egyptian monazite by solvent impregnated foam. Journal of Radioanalytical and Nuclear Chemistry, 289, pp.321-329.

Hussein, A.M., 2018. Natural radioactivity and radon exhalation in the sediment river used in Sulaymaniyah governorate, Iraq, dwellings. ARO-The Scientific Journal of Koya University, 6(2), pp.7-12. Available from: http://aro.koyauniversity.org/article/view/ARO.10381. [Last accessed on 2019 Mar 18].

IAEA., 1989. Measurement of Radionuclides in Food and the Environment. IAEA Technical Report Series No. 295, Vienna. ICRP., 1993. International Commission on Radiological Protection ICRP Publication 65, Annals of the ICRP 23(2).

Pergamon Press, Oxford. Jayasheelan, A., Manjunatha, S., Yashodhara, I., and Karunakara, N., 2013. Study of natural radioactivity and estimation of radiation dose in the environment of Tumkur, Karnataka, India. Radiation Protection Dosimetry, 158(1), pp.73-78.

Jibiri, N.N., and Biere, P.E., 2011. Activity concentrations of232Th, 226Ra and 40K and gamma radiation absorbed dose rate levels in farm soil for the production of different brands of cigarette tobacco smoked in Nigeria. Iranian Journal of Radiation Research, 8(4), pp.201-206.

Kamal, O.A., Salar, Z.M., and Adil, M.H., 2015. Assessment of Rn and U concentrations in the soil of Qadafery, Kalar and Zarayan located in Sulaimani governorate of Kurdistan region-Iraq. American Journal of Environmental Protection, 4(1), pp.40-44.

Kamal, H.K., and Ali, M.S., 2004. Geological formation in Iraqi Kurdistan. Kurdistan Academicians Journal Part A, 4(1), pp.19-39.

Kumar, A., Singh, B., and Singh, S., 2001. Uranium, radium and radon exhalation studies in some soil samples from Una district, Himachal Pradesh, India using track-etching technique. Indian Journal of Pure and Applied Physics, 39, pp.761-764.

Lu, X., and Xiaolan, Z., 2006. Measurement of natural radioactivity in sand samples collected from the Baoji Weihe Sands Park, China. Environmental Geology, 50, pp.977-982.

Makki, N.F., Kadhim, S.H.A., Alasadi, A.H., and Almayahi, B.A., 2014. Natural radioactivity measurements in different regions in Najaf city, Iraq. Journal of Computer Trends and Technology, 9(6), pp.286-289.

Punniyakotti, J., and Ponnusamy, V., 2017. Radionuclides of238U, 232Th and 40K in beach sand of southern regions in Tamilnadu State, India (Post-Tsunami). Indian Journal of Pure and Applied Physics, 55, pp.218-230.

Salih, N.F., 2018. Determination of natural radioactivity and radiological hazards of 226Ra, 232Th, and 40K in the grains available at Penang Markets, Malaysia, using high-purity germanium detector. ARO-The Scientific Journal of Koya University, 6(1), pp.71-77. Available from: http://www.aro.koyauniversity.org/article/view/ARO.10327. [Last accessed on 2019 Mar 18].

SEAM Programme., 2005. Damietta Governorate Environmental Profile, Ministry of State for Environmental Affairs. Egyptian Environmental Affairs Agency, UK.

Snežana, N., Nenadovic, M., Kljajević, L.M., Vukanac, I., Spahić, M.P., Radosavljevic-Mihajlovic, A.S., and Pavlovic, V.B., 2012. Vertical distribution of natural radionuclides in soil: Assessment of external exposure of population in cultivated and undisturbed areas. Science of the Total Environment, 429, pp.309-316.

Sureshgandhi, M., Ravisankar, R., Rajalakshmi, A., Sivakumar, S., Chandrasekaran, A., and Pream, A.D., 2014. Measurements of natural gamma radiation in beach sediments of north east coast of Tamilnadu, India by gamma ray spectrometry with multivariate statistical approach. Journal of Radiation Research and Applied Sciences, 7(1), pp.7-17.

Tufan, M.C., and Disci, T., 2013. Natural radioactivity measurements in building materials used in Samsun, Turkey. Radiation Protection Dosimetry, 156, pp.87-92. UNSCEAR., 2000. Report to General Assembly, with Scientific Annexes, Sources and Effects of Ionizing Radiation, United Nations, New York.

Veiga, R., Sanches, N., Anjos, R.M., Macario, K., Bastos, J., Iguatemy, M., Aguiar, J.G., Santos, A.M., Mosquera, B., Carvalho, C., Filho, M.B., and Umisedo, N.K., 2006. Measurement of natural radioactivity in Brazilian beach sands. Radiation Measurements, 41, pp.189-196.

Zakariya, A.H., Jaafar, S.M., and Asaad, H.I., 2013. Measurement of radium content and radon exhalation rates in building material samples using passive and active detecting techniques. International Journal of Scientific and Engineering Research, 4(9), pp.1827-1831.