Urban Surface Run-Off as a Vector for Soil Contamination in Rapidly Growing Cities in Rivers State, Nigeria
OKIDHIKA, Clinton Umebhidhi PhD, ABULE, Esther Chinyere PhD, OKWELLE, Peace Lawrence PhD
Abstract
Urban surface runoff remains a significant but often underappreciated vector in the transport and deposition of contaminants in soil, especially in rapidly expanding cities such as Port Harcourt, Nigeria. Urbanization and industrialization in Port Harcourt metropolitan city, Nigeria, have intensified environmental concerns, especially relating to the degradation of soil quality through contaminated surface run-off. This study assessed the physicochemical and heavy metal characteristics of surface runoff-impacted soils in Aluu and Elemeβtwo distinct yet environmentally vulnerable zones within the city. Soil samples were analyzed for key parameters, including pH, electrical conductivity (EC), moisture content, total organic matter (TOM), total organic carbon (TOC), total nitrogen (TN), available phosphorus (P), sulfate (SO?Β²?), total hydrocarbon content (THC), total petroleum hydrocarbon (TPH), and heavy metals such as iron (Fe), arsenic (As), cadmium (Cd), lead (Pb), zinc (Zn), copper (Cu), chromium (Cr), and nickel (Ni).The results revealed alarming exceedances of permissible limits across most parameters. Soil pH values ranged from 5.88 in Eleme to 6.42 in Aluu, indicating slightly acidic conditions below the WHO/FAO acceptable range (6.0β8.5). Electrical conductivity was higher in Eleme (265.1 Β΅S/cm) than Aluu (203.4 Β΅S/cm), suggesting elevated ionic concentrations in runoff-receiving soils. Moisture content values were appreciable at 21.83% in Eleme and 19.21% in Aluu. High TOM (6.95% in Eleme) and TOC (4.03%) levels exceeded typical natural soil benchmarks, signifying significant organic loading, likely due to hydrocarbon and waste inflow. Similarly, TN and available phosphorus levels were elevated (0.57% and 15.07 mg/kg respectively in Eleme), pointing to nutrient enrichment that could disrupt native microbial and vegetation communities. More critically, THC and TPH levels far exceeded the NESREA threshold of 50 mg/kg, re
Keywords
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