Determination of Naturally Occurring Radionuclides and Heavy metals in Pegmatite Rock Using Energy Dispersive X-ray Fluorescence (EDXRF)

Taiwo Bukola Fasiku; Musbau Kewulere Fasasi; Adebimpe Amos Amosun

Full Article - PDF Review History

Published: 2023-05-20

Page: 118-128

Issue: 2023 - Volume 6 [Issue 3]

Determination of Naturally Occurring Radionuclides and Heavy metals in Pegmatite Rock Using Energy Dispersive X-ray Fluorescence (EDXRF)

Full Article - PDF Review History

Published: 2023-05-20

Page: 118-128

Issue: 2023 - Volume 6 [Issue 3]

Taiwo Bukola Fasiku *

Department of Physics, Ajayi Crowther University, Oyo, Nigeria.

Musbau Kewulere Fasasi

Center for Energy and Research Development, Obafemi Awolowo University, Ile- Ife, Nigeria.

Adebimpe Amos Amosun

Center for Energy and Research Development, Obafemi Awolowo University, Ile- Ife, Nigeria.

*Author to whom correspondence should be addressed.

Abstract

Aims: This study was to analyse pegmatite rock samples in order to determine the concentrations of naturally occurring radionuclides and heavy metals present in the samples.

Study Design: The samples were analysed using non-destructive Energy Dispersive X-ray fluorescence (EDXRF) spectrometer.

Place and Duration of Study: This work was carried out at the Centre for Energy and Research Development (CERD), Obafemi Awolowo University, Ile- Ife, Osun State, Nigeria between September 2016 and June 2017.

Methodology: In this study, analysis of ten randomly selected rock samples were carried out using EDXRF to determine the concentrations of the naturally occurring radionuclides and heavy metals presence. The elements detected were divided into three groups which include: radionuclides, major and minor elements which were related together using the Pearson correlation coefficient.

Results: The EDXRF analysis confirmed the presence of U (1.54 %), Th (0.40 %), and K (7.85 %) with concentrations higher than their permissible world values of 0.0002.8 %, 0.0007.4 %, and 1.3 %, respectively. The samples contained seven major elements (Fe, Mn, Pb, Ti, La, Ca, and Ta) and fourteen minor elements including some heavy metals (Zn, Sr, Zr, Cr, Nb, Mg, Ce, Re, Hf, V, Al, Nd, Sc, and Y). The results showed a large quantity of Fe with an average value of 37.67 %.

Conclusion: The presence of natural radionuclides and toxic metals like Cr, Pb, and Mn in significant quantity in some of the samples is of serious environmental and public concern. There is an absolute possibility that the heavy metal and the radionuclides find their ways into the natural ecosystem as a result of anthropogenic activities such as mining. This could pose miners, dwellers, and the general populace to a serious health risk.

Keywords: Elemental analysis, energy dispersive x-ray fluorescence, heavy metals, pegmatite, radionuclides

How to Cite

Fasiku , Taiwo Bukola, Musbau Kewulere Fasasi, and Adebimpe Amos Amosun. 2023. “Determination of Naturally Occurring Radionuclides and Heavy Metals in Pegmatite Rock Using Energy Dispersive X-Ray Fluorescence (EDXRF)”. South Asian Research Journal of Natural Products 6 (3):118-28. https://www.journalsarjnp.com/index.php/SARJNP/article/view/117.

Downloads

Download data is not yet available.

References

Glover AS, Rogers WZ, Barton JE. Granitic pegmatites: Storehouses of industrial minerals. Elements. 2012;8(4):269-73.

Simmons WB, Pezzotta F, Shigley JE, Beurlen H. Granitic pegmatites as sources of coloured gemstones. Elements. 2012; 8(4):281-7.

London D, Verplanck PL, Hitzman MW. Rare – element granitic pegmatites. Rare earth and critical elements in ore deposits. Rev Econ Geol. 2016;18:165-94.

Müller A, Simmons W, Wise M, Thomas R, Martin R, Beurlen H et al. Initiative of a new classification of pegmatites – A review of initial thoughts. Abstract Volume of the 21st General Meeting of the International Mineralogical Association 1, Johannesburg, South Africa. 2014;260.

Fersman A. A geochemical genetic classification of pegmatites. Monograph Akademiia Nauli SSSR. (in Russian); 1930. p. 85-9.

Ginsburg AI, Rodionov GG. On the depths of the granitic pegmatite formation. Gearogiya Rudnykh Mestorozhdenyi Lzd Nab Moskva. 1960;1:45-54.

Cern’y P, Ercit TS. The Classification of Granitic pegmatites revisited. Earth Sci. 1981;2(2):81-90.

Tanko IY, Chime P. Geochemistry and mineralization of some selected pegmatite deposits in panda North Central, Nigeria, EJERS, European. J Eng Technol Res. 2021;6(2):58-66.

Mawdsley JB. Uraninite-bearing deposits, Charlebois Lake area, Northeastern, Saskatchewan, Canad, Inst Min Metal. Bull. 1952;482:66-375.

International Atomic Energy Agency (IAEA) geological classification of uranium deposits and selected examples. TecDoc. Vienna, 2018.

Association WN. World uranium mining production; 2020.

Available: https://www.world-nuclear.org/ information-library/nuclear-fuel-cycle/mining-of-uranium/world-uranium-mining-production.aspx

Salonen V, Korkka-Niemi K. Influence of parent sediments on the concentration of heavy metals in urban and suburban soils in Turku, Finland. Finl Appl Eochemisty. 2007;22(5):906-18.

Sodango TH, Li X, Sha J, Bao Z. Review of the spatial distribution, source and extent of heavy metal pollution of soil China: impacts and mitigation approaches. J Health Pollut. 2018;8(17):53-70.

Timothy N, Tagui Williams E. Environmental pollution by heavy metal: an overview. Environ Chem. 2019;3(2):72-82.

Sharma P, Kumar S, Pandey A. Bioremediated techniques for remediation of metal pollutants using metagenomics approaches: A review. J Environ Chem Eng. 2021;9(4):105684.

Azeh Engwa G, Udoka PF, Nweke FN, Unachukwu NM. Mechanism and health effects of heavy metal toxicity in humans poisoning mod. world. New Tricks Old Dog. 2019;82511.

Coetzee JJ, Bansal N, Chirwa EMN. Chromium in environment, its toxic effect from chromite- mining and ferrochrome industries and its possible bioremediation. Expo Health. 2020;12(1):51-62.

Zhao Y, Fang X, Mu Y, Cheng Y, Ma Q, Nian H et al. Metal pollution (Cd, Pb, Zn and As) in agricultural soils and soybean, glycine max, in southern China. Bull Environ Contam Toxicol. 2014;92(4):427-32.

Emurotu JE, Onianwa PC. Bioaccumulation of heavy metals in soil and selected food crops cultivated in Kogi State, North Central Nigeria. Environ Syst Res. 2017;6(1):1-9.

Hasan AB, Reza AHMS, Kabir S, Siddique MAB, Ahsan MA, Akbor MA. Accumulation and distribution of heavy metals in soil and food crops around the ship breaking area in southern Bangladesh associated health risk assessment. SN Appl Sci. 2020;2(2): 1-18.

United Nations Scientific Committee on the Effects of Atomic Radiation. Sources and Effects of Ionizing Radiation, General Assembly with scientific annexes, New York: United Nations Sales Publication. United Nations. 2000;1.

Faweya EB, Adesakin GE, Faweya O. X-ray fluorescence (XRF) analysis of rock and soil samples from a magnetic intrusive rock in Oba Akoko, Nigeria. Adv Phys. 2016;11(9):4043-53.

Ajayi OS, Dike CG, Balogun KO. Elemental and radioactivity analysis of rocks and soils of some selected sites in southwestern Nigeria. Environmental Forensic. 2018;19(2):87-98.

Orosun MM, Usikalu MR, Oyewumi JO, Achuka JA. Radioactivity levels and transfer factor for granite mining field in Asa, North- Central Nigeria. J Heliyon. 2020;6(6):e04240: 1-6.

Harvey B, Robert JT. Petrology. 2nd Ed. New York: Freeman.1997;66.

Jan S, Victor AD, Douglas KM, Jean CCH, Dennis DE. Quantitative X-ray diffraction analysis of clay- bearing rocks from random preparations. Clays Clay Miner. 2001;49:6 (Galley 59).

Isinkaye MO. Distribution of Heavy metals and Natural Radionuclide in Selected Mechanize Agricultural Farmlands within Ekiti State, Nigeria. Arab J Sci Eng. 2012;37(5):1483-90.

Kolapo AA, Omoboyede JO. Health Risk Assessment of Natural Radionuclide and Heavy metals in commonly consumed Medicinal plants in South- West Nigeria. IFE J Sci. 2018;20(3):529-37.

Okeyode IC, Makinde V, Bada BS, Mustapha AO, Jegede OA, Ajayi OA et al. Concentration of Natural radionuclides and Heavy Metals in Quarry pit soils in Abeokuta, Ogun State, South West Nigeria. Niger J Phys. 2018;27(2): 84-92.

Arogunjo AM. Heavy metal composition of some solid minerals in Nigeria and their Health implications to the Environment. Pak J Biol Sci. 2007;10(24): 4438-43.

Samia ME, Amany TS, Najat FA, Saher MD. XRF analysis of heavy metals for surface soil of Qarun Lake and wadi el Rayan in Faiyum, Egypt. Open J Met. 2013;3:21-5.

Mohammed MS. Chemical and Structural analysis of Rocks using X-ray fluorescence and X-ray diffraction Techniques. 2020; 79-87.

Lowemark I, Chen HE, Yang TN, Kylander M, Yu EF, Hsu YW et al. Normalising XRF scanner data; A cautionary note on the on the interpretation of high resolution records from organic – rich lakes. J Asian Earth Sci. 2011;40:1250-6.

Isinkaye MO, Shitta MB, Oderinde MO. Determination of radionuclides and elemental composition of clay soils by gamma- and X-ray spectrometry. SpringerPlus. 2013;2(74):2-11.

Matheis G, Caen-Vachette M. Rb – Sr Isotopic study of Rare Metal Bearing and Barren pegmatites in the Pan-African Reactivation Zone of Nigeria. J Afr Earth Sci. 1983;1(1):35-40.

Kinnaird JA. Contrasting styles of Sn-Nb-Ta-Zn mineralization in Nigeria. J Afr Earth Sci. 1984;2(2):81-90.

Fasiku TB, Fasasi MK, Amosun AA. Measurement of Radioactivity concentration in pegmatite Rocks samples and Dose Assessment from Wamba in North Central, Nigeria. AJOPACS. 2022;10(3):45-53.

Olabanji SO, Omobuwajo OR, Ceccato D, Buoso MC, De Poli M, Moschini G. Analysis of some medicinal plants in south-western Nigeria using PIXE. J Radioanal Nucl Chem. 2006;270(3):515-21.

Joseph CIM, Havstad, Ownby, DR, Peterson EI, Maliarik M, McCabe MJ. Blood lead level and risk of asthma. Environ. Health Perspect. 2005;113(7): 900-904.

Jacobs DE, Wilson J, Dixon SL, Smith J, Evens A. The relationship of housing and population health: a 30 – year retrospective analysis. Environ Health Perspect. 2009;117(4):597-604.

Kianoush S, Balali-Mood M, Mousavi SR, Moradi V, Sadeghi M, Dadpour B et al. Comparison of therapeutic effects of garlic and d- penicil amine in patients with chronic occupational lead poisoning. Basic Clin Pharmacol Toxicol. 2012;110(5): 476-81.

Calabrese E. Nutrition and environmental health: the influence of nutritional status on pollutant toxicity and carcinogenicity. New York: John Wiley & Sons; 1981.

Adewale OO, Tubosun IA, Ojo JO. Assessment of Terrestrial naturally occurring radioactive material in soil and mine tailings of Awo Ede, Osun State, Nigeria. IFE J Sci. 2015;17(1):199-209.

Tchounwou PB, Yedjou CG, Patlolla AK, Sutton DJ. Heavy metal toxicity and the environment. Mol. Clin. Environ Toxicol. 2012;101:133-64.

Loomis D, Guha N, Hall AL, Straif K. Identifying occupational carcinogens: an update from the IARC monographs. Occup Environ Med. 2018;75(8):593-603.

Nickens KP, Patierno SR, Ceryak S. Chromium genotoxicity: a double-edged sword. Chem Biol Interact. 2010; 188(2):276-88.

Faweya EB, Adesakin GE, Faweya O. X-ray fluorescence (XRF) analysis of rock and soil samples from a magnetic intrusive rock in Oba Akoko, Nigeria. Adv Phys. 2016;1(19):4043-53.

Nielsen FH. The importance of diet composition in ultra-trace element. Res. J Nutr. 1985;115(10):1239-47.

Wu Y. Element background levels in soils of Liaohe River Plane. J Environ Sci (China). 1990;3(1):55-73.

Samia ME, Amany TS, Najat FA, Saher MD. XRF analysis of heavy metals for surface soil of Qarun Lake and wadi el Rayan in Faiyum, Egypt. Open J Met. 2013;3:21-5.

Ikoko LAN, Briggs-Kamara MA, Sigalo FB, Ideriah TJ, Ude HN. Elemental composition analysis of soil samples from Bayelsa State in the Niger Delta region of Nigeria. J Appl Sci Environ Manag. 2022;26(4):745-50.

Adam MM, Osman MM, Elhag AS, Elsheikh MA. ICP/XRF Analysis fir Trace Elements in Soil Samples from Gezira and Ski Schemes, Sudan. Int J Sci Res Manag. 2021;9(2):32-9.

Antoaneta E, Alina BS, Lucian G. Determination of heavy metals in soils using XRF technique. Rom J Phys. 2009;55(7-8):815-20.