Assessment of Natural Radioactivity in Drinking Water from some Selected Districts of Michika, Adamawa State, Nigeria

Suleiman  Saidu Zarma; Nuraddeen  Nasiru Garba; Nasiru Rabiu; Umar Muhammad Dankawu; Suleiman Bello; Adamu David Gaima Kafadi; Chifu E. Ndikilar

doi:10.54117/gjpas.v3i1.130

Authors

Suleiman Saidu Zarma Department of Physics, Ahmadu Bello University Zaria, Kaduna State, Nigeria
Nuraddeen Nasiru Garba Department of Physics, Ahmadu Bello University Zaria, Kaduna State, Nigeria
Nasiru Rabiu Department of Physics, Ahmadu Bello University Zaria, Kaduna State, Nigeria
Umar Muhammad Dankawu Department of Physics, Federal University Dutse, Dutse, Jigawa State, Nigeria
Suleiman Bello Department of Physics, Ahmadu Bello University Zaria, Kaduna State, Nigeria
Adamu David Gaima Kafadi Department of Physics, Federal University Dutse, Dutse, Jigawa State, Nigeria
Chifu E. Ndikilar Department of Physics, Umaru Musa Yar’adua University, Katsina State, Nigeria

DOI:

https://doi.org/10.54117/gjpas.v3i1.130

Abstract

Radionuclides are source of radiation that were recorded to have damaging health effects for people living in a community with high back-ground radiation. This study was carryout to assess natural radioactivity in drinking water sources at some districts of Michika, Adamawa State, Nigeria. Twenty-four (24) water Samples from three different sources (surface, borehole and well), were collected and analyzed using a thallium activated 3ʺ x 3ʺ sodium iodide [NaI (TI)] detector connected to ORTEC 456 amplifier available at Center of Energy Research and Training (CERT), Zaria. The results show that the mean activity concentration for ²²⁶Ra, ²³²Th and ⁴⁰K are 57.05, 40.31 and 193.6 Bql^-1 for borehole samples, 82.09, 23.0 and 199.4 for surface samples and 87.65, 38.82 and 215.7 for well samples. These values are higher than the control value of activity concentration set by UNSCEAR 200). The mean absorbed dose rate (D) for borehole, surface and well water samples were found to be 58.78, 60.1 and 72.94 nGy/h respectively. The mean values surface and well samples were higher than the maximum accepted value of 59nGy/h as recommended by (UNSCEAR, 2000) however, borehole is within the MCL. The mean values of total annual effective dose for borehole, surface and well water samples were 0.08, 0.08 and 0.09 respectively. These values are below 0.12, 0.1 and 1.0 mSvy^-1 as recommended by UNSCEAR, WHO and ICRP. Also, the mean values of Radium Equivalent Activity were 129.6, 130.4 and 159.8 Bql^-1 for borehole, surface and well water samples respectively. All the value of R_aeq were below the maximum recommended value of 370 Bql^-1. The mean value of total cancer risk is 3.18E-06, 3.25E-06 and 3.91E-06 for borehole, surface and well water samples respectively. All the mean values were above the acceptable range of 1E-06 to 1E-04. Based on our findings, the water sources in this area are not safe for domestic use. However continuous radiological monitoring of the water is recommended to safeguard the health of the populace.

References

Abba, L., Nasiru, R., Garba, N. N. and Ahmed, Y. A. (2020). Assessment of Annual Effective dose due to Inhalation and Ingestion of Radon in Water Samples from the Cement Industrial Area of Sokoto, Northwestern Nigeria. FUDMA Journal of Sciences (FJS). Vol. 4:(2), pp 615 – 619 DOI: https://doi.org/10.33003/fjs-2020-0402-172.

Ahmed N. K. (2004) Natural radioactivity of ground and drinking water in some areas of Upper Egypt. Turkish Journal of Engineering and Environmental Sciences, 28(6): 345354. 29.

Alaboodi, A.S. N.A. Kadhim, A.A. Abojassim, A. Baqir Hassan. (2020) Radiological hazards Due to natural radioactivity and radon concentrations in water samples at Al-Hurrah city, Iraq. International Journal of Radiation Research. 12(2) 204-219.

Aregunjo, A. M., Farai, I. P., &Fuwape, I. A. (2004). Impact of oil and gas industry on the natural radioactivity distribution in the Delta region of Nigeria. Nigeria Journal of Physics 16 (131), 136.

Asaduzzaman, K.H., Khandaker, M.U., Amin, Y.M., Bradley, D.A. (2016). Natural radioactivity levels and radiological assessment of decorative building materials in Bangladesh. Indoor and Built Environment Vol.25, No.3, pp 541–550.

Belivermis, M., Kilic O., Crytuk, Y., Topcough S. (2009). The effects of physiochemical Properties of gamma emitting natural radionuclide level in the soil profile of Istanbul, Environment monitoring and assessment 163:15-16.

Chifu E. Ndikilar, Shittu Abdullahi and Daniel K. Ayuba. (2016). Determination of Radioactivity Concentration and Estimation of Annual Effective Dose for All Age Categories of Drinking Water Collected from Dutse Town, Nigeria. IOSR Journal of Applied Physics (IOSR-JAP) Vol.8, No.3, pp 13-22 www.iosrjournals.org

Dankawu UM, HY Shuaibu, MN Maharaz, T. Zangina, FM Lariski, M. Ahmadu, SS Zarma, JN, Benedict, M. Uzair, G.D Adamu, and A. Yakubu. (2021). Estimation of Excess Life Cancer Risk and Annual Effective Dose for Boreholes and Well Water in Dutse, Jigawa State Nigeria. DUJOPAS Vol.7 No.4b, pp. 113-122.

Fatima I, Zaidi JH, Arif M, Tahir SNA (2006) Measurement of natural radioactivity in bottled drinking water in Pakistan and consequent dose estimates. Radiation Protection Dosimetry, 123(2): 234-240

Garba N. N, N. Rabi’u, B. B. M. Dewu, U. Sadiq and Y. A. Yamusa (2013). Radon assessment in Ground water sources from Zaria and environs, Nigeria. International Journal of Physical Science Vol. 8(42), pp. 1983-1987 DOI: 10.5897/IJPS2013.4035

Hassan AB, Mohsen AAH, Mraity HAA, Abojassim AA. (2018). Determination of Alpha Particles Levels in Blood Samples of Cancer Patients at Karbala Governorate, Iraq. Iran J Med Phys; Vol.16: 41-47.10.22038/ijmp.2018.32376.1383.

Ibrahim M, Shalabiea O, Diab H (2014) Measurement of some radioactive elements in drinking water in Arar city, Saudi Arabia. American journal of life sciences, 2(1): 24-28.

ICRP. (2007). 2006 recommendations of the International Commission on Radiological Protection, ICRP Publication 103, Pergamon Press, Oxford.

ICRP (2012). Compendium of Dose Coefficients based on ICRP Publication 60. ICRP Publication 119. Ann. ICRP 41(Suppl.).

Jibiri, N.N., Farai, I.P. and Alausa, S.K. (2007). Activity concentration of Ra-226, Ra-228 and K 40 in food crops from a high background radiation area in Bisichi Jos, Plateau State. Nigeria Radiation environmental biophysics. 46:53-59.

Lydie RM and Nemba RM (2009). The annual Effective dose due to natural radionuclides in the reservoir and tap water in Yaoundé area, Cameroon. The South Pacific Journal of Natural and Applied Sciences, 27(1): 61-65.

Nur A. and Ayuni K.N (2011). Hydro-geophysical study of Michika and environs, northeast Nigeria. International Journal of the Physical Sciences Vol. 6(34), pp. 7816 - 7827, 16 DOI: 10.5897/IJPS11.476.

Ononugbo C. P. and Anyalebechi1 C. D. (2017). Natural Radioactivity Levels and Radiological Risk Assessment of Surface Water from Coastal Communities of Ndokwa East, Delta State, Nigeria. Physical Science International Journal vol. 14 No. 1, pp 1-14, Article no.PSIJ.31782. www.sciencedomain.org.

Shittu Abdullahi, Chifu E. Ndikilar, A. B. Suleiman, and Hafeez Y. Hafeez, (2016). “Assessment of Heavy Metals and Radioactivity Concentration in Drinking Water Collected from Local Wells and Boreholes of Dutse Town, North West, Nigeria.” Journal of Environment Pollution and Human Health, vol. 4, no. 1, pp1-8. doi: 10.12691/jephh-4-1-1.

Tchokossa P., J.B. Olomo, O.A. Osibote (1999). Radioactivity in the community water supplies of Ife-Central and Ife-East local government areas of Osun State, Nigeria. UNSCEAR. (2000). Sources and Effects of Ionizing Radiation. United Nation Scientific Committee on the Effects of Atomic Radiation Sources to the General Assembly with Annexes, Effects and Risks of Ionizing Radiation. United Nations publication, New York.

USEPA (1989). Risk assessment guidance for Superfund. Human health evaluation manual, (part A) [R], vol. 1. Washington, DC: Office of emergency and remedial response EPA/540/189/002, USA.

Walliams, P.J., M.D. Barton, D.A. Johnson, L. Fontbote, A. De Haller, G. Mark, N.H.S. Oliver and R. Marschik (2015), Iron oxide copper-gold deposits: geology, space-time distribution, and possible modes of origin, Economic Geology 100th Anniv. Vol., 371-405.

WHO, World Health Organization (2002). Guidelines for Drinking Water Quality: Radiological aspects, at http://www.who.int/water_sanitation_health/dwq/gdwq3rev/en/S. WHO, World Health Organization (2006). Guidelines for Drinking Water Quality: 3rd edition. Chapter 9; Radiological aspects. At http://www.who.int/water_sanitation_health/dwq/gd wq3rev/en/index.

Xinwei, L., Lingqing, W., Xiaodan, J., Leipeng, Y., Gelian., D., (2006). Specific activity and hazards of Archeozoic-Cambrian rock samples collected from the Weibei area of Shaanxi, China. Radiation protection and dosimetry. 118, 352-359.

Ziqiang P, Yin Y, Mingqiang G (1988) Natural radiation and radioactivity in China. Radiation, Protection Dosimetry, 24 (1-4): 29-38.

Nwankwo LI (2012). Study of natural radioactivity of groundwater in Sango-Ilorin, Nigeria. Journal of Physical Science and Application, 2(8): 28. 37.

Zarma S.S, N.N Garba, N Rabiu, U.M Dankawu, S Bello and Chifu E. Ndikilar. (2023). Assessment of Heavy Metal Concentration in Drinking Water sources from some Selected Districts of Michika, Adamawa State, Nigeria. Dutse Journal of Pure and Applied Science, DUJOPAS 9 (1a): pp 168-176.

Zarma S.S, N.N Garba, N Rabiu, U.M Dankawu, S Bello GD Adamu and Chifu E. Ndikilar. (2023). Assessment of Natural Radionuclide in Soil Samples from Michika, Adamawa State, Nigeria. FUDMA Journal of Sciences (FJS) VOL/7 No. 4, August, 2023, pp 189-194.