Abstract
An assessment of the groundwater in areas underlain by pegmatite in Ede, southwestern Nigeria was carried out to determine the concentration of Potassium-40 (40K), Uranium-238 (238U) and Thorium-232 (232Th) radionuclides. In the earlier work, it was established that zircons in these pegmatites have suffered a high degree of metamictization that has enhanced continuous loss of some radionuclides since the time of emplacement of the pegmatite host rock to the present. The aim of this work is to determine whether or not there is corresponding increase in the concentration of radionuclides in groundwater in the study area. Fifteen groundwater samples were collected from both hand dug wells and boreholes in the area. Ten samples were from Ede town, two samples each from nearby communities of Iddo and Ekuro and one from Iwoye, where the bedrocks were not pegmatites. All the 15 samples were analyzed with the Sodium Iodide scintillator (NaI [Tl]) detector at the Centre for Energy Research and Development, Obafemi Awolowo University, Ile-Ife, Nigeria. The results showed varying concentrations of the radionuclides in the water samples. Activity concentrations of Potassium-40 (40K) indicated an average value of 17.149 Bq/L for samples from Ede, 9.265 Bq/L for Iddo, 6.6 Bq/L for Ekuro, while Iwoye has a value of 21.21 Bq/L. The Uranium-238 (238U) series had an average value of 13.64 Bq/L for Ede, 13.49 Bq/L for Ekuro, 11.685 Bq/L for Iddo and 12.04 Bq/L for the lone sample from Iwoye. Thorium-232 (232Th) series had an average value of 11.182 Bq/L for Ede, while average values of 7.79 Bq/L and 9.025 Bq/L, respectively, were recorded for Iddo and Ekuro and 12.25 Bq/L for Iwoye. The annual effective dose level of 40K is generally below the World Health Organization (WHO) recommended dosage of 0.1 mSv/y except for three locations, while those of 238U and 232Th are in excess of the standard values. The high radionuclides in the groundwater in the study area were not due to anthropogenic sources but directly due to geological processes which release the radioisotopes from rocks after weathering, continuous loss from metamict minerals and natural lateral mobility from regions of radionuclides’ release to other areas. There is thus the need to carry out systematic studies of the radionuclides concentrations on regional scale in the area which could lead to investigating on both short- and long-term health effects on organic species in these areas, and development of purification systems before utilizing water from the areas for domestic and industrial purposes.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Adetunji A (2012) Geochemical and petrogenetic studies of pegmatites in some part of Osun State. Unpunbl Ph.D. thesis, Obafemi Awolowo University, Ile-Ife, Nigeria. p 286
Adetunji A, Olarewaju VO, Ocan OO, Ganev VY, Macheva L (2016) Geochemistry and U-Pb zircon geochronology of the pegmatites in Ede area, southwestern Nigeria: a newly discovered oldest Pan-African rock in southwestern Nigeria. J Afr Earth Sci 115:177–190
Ahmed NK (2004) Natural radioactivity of ground and drinking water in some areas of upper Egypt. Turk J Eng Environ Sci 28:345–354
Ajayi OS, Adesida G (2009) Radioactivity in some sachet drinking water samples produced in Nigeria. Iran J Radiat Res 7(3):151–158
Ajayi OS, Owolabi TP (2008) Determination of natural radioactivity in drinking water in private dug wells in Akure, southwestern Nigeria. Radiat Prot Dosim 128(4):477–484
Ajayi IR, Ajayi OS, Fusuyi AS (1995) The natural radioactivity of surface soils in Ijero-Ekiti. Niger J Phys 7:101–103
Akinloye MK (1998) Measurement of outdoor gamma exposure rate and levels of Obafemi Awolowo University environment, Ile-Ife. Unpubl Ph.D. thesis, Obafemi Awolowo University, Ile-Ife, Nigeria
Alam MN, Chowdhury MI, Kamal M, Ghose S, Islam MN, Anwaruddin M (1999) Radiological assessment of drinking water of Chittagong region of Bangladesh. Radiat Prot Dosim 82(3):207–214
Burke KC, Dewey JF (1972) Orogeny in Africa. In: Dessauvagie TFJ, Whiteman AJ (eds) Africa geology. University of Ibadan Press, Ibadan, pp 583–608
Dada SS (2006) Proterozoic evolution of Nigeria. In: Oshin O (ed) The Basement Complex of Nigeria and its mineral resources (A Tribute to Prof Rahaman MAO). Akin Jinad and Co, Ibadan, pp 29–44
Farai IP, Sanni AO (1992) Year long variability of Rn-222 in a groundwater system in Nigeria. J Afr Earth Sci 15(3–4):399–403
IAEA (1996) International basic safety standards for protection against ionizing radiation and for the safety of radiation sources. International Atomic Energy Agency, Vienna
ICRP (1991) The 1990 recommendations of the ICRP. Annals of the ICRP 21(1.3). Pergamon Press (International Commission on Radiological Protection Publication 60), Oxford
ICRP (2000) Protection of the public in situations of prolonged radiation exposure. Pergamon Press (International Commission on Radiological Protection), Oxford
Jubri NN, Mabawonku AO, Oridate AA, Ujiagbedion AJ (1999) Natural radionuclide concentration levels in soil and water around a cement factory at Ewekoro, Ogun State, Nigeria. Niger J Phys 11:12–16
Lydie RM, Nemba RM (2008) Quantitative determination of 226-Ra and 228-Ra in reservoir and tap water in Yaoundé area, Cameroon. Glob J Environ Res 2(3):110–113
Lydie RM, Nemba RM (2009) The annual effective dose due to natural radionuclides in the reservoir and tap water in Yaoundé area, Cameroon. S Pac J Nat Sci 27:61–65
Nasirian M, Bahari I, Abdullah P (2008) Assessment of natural radioactivity in water and sediment from Amang (tin tailing) processing ponds. Malays J Anal Sci 12(1):150–159
Nguelem EJM, Darko EO, Ndontchueng MM, Schandorf C, Akiti TT, Muhulo AP, Dogbey ROG (2013) Assessment of natural radioactivity level in groundwater from selected areas in Accra metropolis. Res J Environ Earth Sci 5(2):85–93
Nour KA (2004) Natural radioactivity of ground and drinking water in some Areas of Upper Egypt. Turk J Eng Environ Sci 28(6):345–354
Nwankwo LI (2008) Determination of radioactivity level in groundwater in a part of Basement complex terrane of Ilorin, Nigeria. Niger J Phys 20(2):353–358
Nwankwo LI (2010) Annual effective dose due to combined concentration of 226-Ra and 228-Ra in the groundwater system: a case study of the University of Ilorin main campus, Nigeria. Facta Univ Ser Work Living Environ Prot 7(1):53–58
Nwankwo LI (2012) Study of natural radioactivity of groundwater in Sango-Ilorin, Nigeria. J Appl Phys Sci 2(8):289–295
Nwankwo LT (2013) Determination of natural radioactivity in groundwater in Tanke Ilorin, Southwestern, Nigeria. West Afr J Appl Ecol 21(1):111–119
Olise FS, Akinnagbe MD, Olasogba OS (2016) Radionuclides and radon levels in soil and groundwater from solid minerals located area, southwestern Nigeria. Cogent Environ Sci 2(1):282–300
Oyawoye MO (1967) The petrology of a potassic syenite and its associated biotite pyroxenite at Shaki, Western Nigeria. Contrib Miner Petrol 16:115–138
Rahaman MA (1976) Review of the basement geology of southwestern Nigeria. In: Kogbe CA (ed) Geology of Nigeria. Elizabethan Publishers, London, pp 41–58
Rahaman MA (1988) Recent advances in the study of the Basement complex of Nigeria. In: Oluyide PO, Mbonu WC, Ogezi AE, Egbuniwe IG, Ajibade AC, Umeji AC (eds) Precambrian geology of Nigeria. Geological Survey of Nigeria spec pub, Ilorin, pp 11–41
WHO (2006) Guidelines for drinking water quality (electronic resource) incorporating first Addendum, vol 1, 3rd edn. pp 197–209 (ISBN G 241546964)
Witheril GW (1956) An interpretation of the Rhodesia and Witwatersrand age patterns. Geochim Cosmochim Acta 9:282–290
Acknowledgements
We thank the owners of wells and boreholes who provided permission for the sampling. Without their cooperation this study would not have been possible.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Adetunji, A., Olorunfemi, A.O., Abe, O. et al. Anomalous concentrations of radionuclides in the groundwater of Ede area, southwestern Nigeria: a direct impact of geology. Environ Earth Sci 77, 618 (2018). https://doi.org/10.1007/s12665-018-7799-2
Received:
Accepted:
Published:
DOI: https://doi.org/10.1007/s12665-018-7799-2