Comparison of the Geotechnical Properties of Lateritic Soils of Borrow Pits for Road Construction in Ado Ekiti
Article Sidebar
Main Article Content
Abstract
Lateritic soils are key materials in road construction across tropical regions, but their performance varies based on their geotechnical properties. This study analyzes the geotechnical properties and characteristics of lateritic soils from selected borrow pits in Ado Ekiti, Nigeria, to determine their suitability for subbase and subgrade applications. Four borrow pits, labeled A to D, were randomly selected, and twelve undisturbed soil samples (three from each pit) were collected for laboratory testing. The tests include natural moisture content, specific gravity, grain size distribution, Atterberg limits, permeability, compaction, California Bearing Ratio (CBR), unconfined compressive strength (UCS), and triaxial test. Soil samples from Borrow Pit A, identified as Silty Sand (SM) and classified as A-2-4, showed the highest Maximum Dry Density (1750–1753 kg/m³), low Optimum Moisture Content (12%–14%), fines content of 12%, adequate permeability (2.0 × 10⁻⁵ to 2.2 × 10⁻⁵ cm/s), and unsoaked CBR values of 70%–75%, making them ideal for subbase applications. Borrow Pit B soil samples, categorized as Clayey Sand (SC) and A-2-6, had moderate MDD values (1650–1660 kg/m³), permeability between 1.2 × 10⁻⁵ and 1.4 × 10⁻⁵ cm/s, unsoaked CBR values of 58%–60%, and shear strength of 205–210 kPa, making them suitable for improved subgrades or low-traffic subbases. Borrow Pits C and D, classified as Low Plasticity Clay (CL) under USCS and A-6 and A-7-6 under AASHTO, had MDD values between 1500–1551 kg/m³, fines content of 20%–30%, permeability between 0.4 × 10⁻⁵ and 0.1 × 10⁻⁵ cm/s, unsoaked CBR values below 42%, and shear strength of 180–192 kPa, making them more appropriate for subgrade applications. The study concludes that Borrow Pit A is the most suitable for subbase layers, while Borrow Pits B, C, and D require stabilization, such as lime or cement treatment, to improve their strength and plasticity properties.
Downloads
Article Details
This work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License.
References
Amu, O., Ogunniyi, S. & Oladeji, O. (2011). Geotechnical properties of lateritic soil stabilized with sugarcane straw ash. American Journal of Scientific and Industrial Research., 2(2), 323–331, doi: 10.5251/ajsir.2011.2.2.323.331.
Abimiku, J., Pogu, J.H. & Bala, A.B. (2015). Suitability of Afaka Borrow Pit for Subgrade and Base Materials. Journal of Science and Multidisciplinary Research., 7(1).
Ehujuo, N., & Akaolisa, C.C.Z. (2019). Geotechnical Properties of Lateritic Soils Derived from Various Geologic Formations in Okigwe Area, Southeastern Nigeria. Futo Journal Series., 3(2), 178–189.
Thankam, N.S., Rekha, V., & Shankar, U. (2017). Use of lateritic soil amended with bentonite as landfill liner. Rasayan Journal of Chemistry, 10(4), 1431–1438, doi: 10.7324/RJC.2017.1041818.
Janet, A.Y., Sunday, S.D., Rhoda, B.G., Edwin, D.E. & Mbushu, C. M. (2023). Causes of failure of Nigerian roads: A review. World Journal of Advanced Engineering Technology and. Sciences., 8(2), 217–223,,doi: 10.30574/wjaets..8.2.0079.
Amu, O.O., & Salami, B.A. (2010). Effect of Common Salt on Some Engineering Properties of Eggshell Stabilised Lateritic soil. ARPN Journal of Engineering and Applied. Sciences, 5(9), 64–73.
Adams, J.O. & Adetoro, A.E. (2014). Analysis of road Pavement Failure Caused by Soil Properties along Adoekiti - Akure road,Nigeria. International Journal of Novel Research in Engineering and Applied Sciences, 1(1), 1–7.
Degu, D., Fayissa, B., Geremew, A., & Chala, G. (2022). Investigating Causes of Flexible Pavement Failure: a Case Study of the Bako To Nekemte Road, Oromia, Ethiopia. Journal of Civil Engineering Science and Technology, 13(2). 112–135, doi: 10.33736/jcest.4332.
Adunoye, G., Onah, O. & Ajibade, F. (2019). Experimental Study of the Effects of Some Selected Geotechnical Indices on the Unconfined Compressive Strength of Lateritic Soil. LAUTECH Journal of Civil and Environmental. Studies, 2(1), doi: 10.36108/laujoces/9102/20(0180).
Ugwuanyi, H. K., & Onyelowe, K. C. (2019). Suitability of Olokoro and Amaoba Lateritic Soil as Pavement Construction Materials. Nigerian Journal of Technology (NIJOTECH), 38(3), 549–556. https://doi.org/http://dx.doi.org/10.4314/njt.v38i3.2
Graue, B., Siegesmund, S., Oyhantcabal, P., Naumann, R., Licha, T. & Simon, K. (2013). The effect of air pollution on stone decay: The decay of the Drachenfels trachyte in industrial, urban, and rural environments-a case study of the Cologne, Altenberg and Xanten cathedrals. Environmental Earth Science, 69(4), 1095–1124, doi: 10.1007/s12665-012-2161-6.
Adiat, K.A.N., Akinlalu, A.A. & Adegoroye, A.A. (2017). Evaluation of road failure vulnerability section through integrated geophysical and geotechnical studies. NRIAG Journal of Astronomical. Geophysics., 6(1), 244–255, doi: 10.1016/j.nrjag.2017.04.006.
A. R. (2024). A Review of Road Pavement Failure: A Case Study of Nigerian Road. Advanced Journal of Science Technology Engineering., 4(2), 8–23, doi: 10.52589/ajste-mvcd6edz.
Ayodele, A.L., Falade, F.A. & Ogedengbe, M.O. (2000). Effect of fines content on some engineering properties of lateritic soil in Ile-Ife. Journal of Engineering Research, 14(1), 10-20
Adebayo, O.A. & Oloruntola, M.O. (2020). Evaluation of Sub Base / Subgrade Soils Along Ikorodu-Shagamu Road. Proceedings of the First International Conference of the Nigerian Association of Engineering Geology and the Environment, 7, 1–10
H.A.P. A & O. J. O. (2019). Experimental Study on Effect of Lime and Cement Stabilizers on Geotechnical Properties of Lateritic Soil. International Journal of Engineering Research and Advanced Technology, 5(4), 09–15, doi: 10.31695/ijerat.2019.3409.
Mohammed Y., Afzal K., & Argaw A. (2023). Geotechnical Properties of Tropical (Lateritic) Soils and Their Implications for Road Construction: A Case Study from Bahir-Dar, Ethiopia. Geotechnical Engineering Journal of the SEAGS & AGSSEA, 54(2), 1-10
Mohit, S. & Ivan, G. (2025). The effect of rainfall patterns on the swelling behaviour of expansive soil International Journal of Geotechnical Engineering, 19