Asian Journal of Geological Research

Groundwater resources under tropical climates face escalating pressures from climate change and anthropogenic activities. The eastern flank of Mount Cameroon a critical agro-industrial zone exemplifies these challenges, yet comprehensive assessments integrating hydrogeochemical and isotopic evidence remain limited. 50 groundwater samples (boreholes, springs, wells) and 14 precipitation events. In-situ parameters (pH, EC, temperature) were measured followed by laboratory quantification of major ions (ion chromatography), trace elements (ICP-MS), and stable isotopes (δ¹⁸O, δ²H; cavity ring-down spectroscopy). Hydrochemical facies and recharge processes were evaluated using Aquachem, Piper diagrams, and Local Meteoric Water Line (LMWL) regression. Three dominant hydrochemical facies were identified: Ca-Cl (74%), indicating ion exchange and evaporite dissolution; Ca-HCO₃ (20%), reflecting active recharge and carbonate weathering; and mixed Ca-Mg-Cl (6%). Groundwater exhibited low mineralization (mean TDS: 102.24 mg/L; EC: 314.94 µS/cm) but localized Fe (≤5.31 mg/L) and Mn (≤3.28 mg/L) exceeded WHO thresholds. Isotopic signatures (δ¹⁸O: −2.90 ± 0.46‰; δ²H: −11.39 ± 1.99‰) confirmed precipitation as the primary recharge source, with d-excess values (9.96‰) indicating minor evaporation. A 15% precipitation decline (1991–2020) correlated with enriched δ¹⁸O-Cl⁻ trends, signalling climate-induced recharge vulnerability. The aquifer’s sustainability is threatened by climate-driven precipitation variability, geogenic contamination (Fe/Mn), and agricultural pollutants. Targeted monitoring of shallow zones, protection of fracture-mediated recharge systems, and climate-resilient policies are imperative for water security. This study establishes a critical baseline for sustainable management of volcanic aquifers in tropical regions.