Sequential Extraction, Mobility, and Pollution Loading of Heavy Metals in Soils from the Ikole–Itapaji Area, Southwestern Nigeria.
Authors
Department of Geology, Faculty of Physical Sciences, Ekiti State University, Ado Ekiti. (Nigeria)
Department of Geology, Faculty of Physical Sciences, Ekiti State University, Ado Ekiti. (Nigeria)
Department of Geology, Faculty of Physical Sciences, Ekiti State University, Ado Ekiti. (Nigeria)
Article Information
DOI: 10.51584/IJRIAS.2026.11060111
Subject Category: Environment
Volume/Issue: 11/6 | Page No: 1425-1453
Publication Timeline
Submitted: 2026-06-07
Accepted: 2026-06-12
Published: 2026-06-27
Abstract
This study investigates the sequential extraction, mobility, and pollution loading of heavy metals in soils from the Ikole–Itapaji area, Southwestern Nigeria. Soil samples collected from seventeen locations were analyzed using a modified seven-step Tessier sequential extraction procedure to partition metals into water-soluble, exchangeable, carbonate-bound, Fe–Mn oxide-bound, organic matter-bound, sulfide/strongly bound, and residual fractions. The objective was to evaluate metal speciation, mobility, and environmental risk using Contamination Factor (CF) and Pollution Load Index (PLI) as complementary pollution indices. Results show that most heavy metals are predominantly concentrated in the residual and Fe–Mn oxide fractions, indicating strong lithogenic control and low overall mobility within the soil system. The carbonate-bound, organic matter-bound, and sulfide fractions also contribute moderately to total metal retention, while the water-soluble and exchangeable phases contain relatively low concentrations, suggesting limited immediate bioavailability under present environmental conditions. However, elevated CF values for Cd and Pb indicate significant enrichment, with Cd reaching severe contamination levels at several sampling locations. The Pollution Load Index reveals that most sites have PLI values greater than 1, indicating overall soil quality deterioration, with pronounced contamination hotspots at SQ3, SQ4, SQ14, and SQ15. These spatial patterns reflect a combination of natural geological background variation and localized anthropogenic inputs. The study concludes that although the geochemical framework of the area is largely dominated by stable lithogenic sources, Cd and Pb represent key environmental concerns. The results highlight the effectiveness of sequential extraction in assessing metal mobility, pollution status, and ecological risk in basement complex terrains.
Keywords
Sequential extraction, Contamination, Anthropogenic input, Basement complex
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References
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