<p>The present study investigates the geoenvironmental characteristics and mobility of heavy metals in gold mine tailings collected from a mining region in western India. The tailings were subjected to comprehensive physical, mineralogical, and geochemical characterization, including particle size distribution, XRD-based mineralogy, XRF elemental composition, ICP-OES based total heavy metal analysis, and sequential extraction to evaluate metal speciation and environmental risk. Results indicate that the tailings are fine-grained (&lt; 45&#xa0;μm) with a slightly alkaline nature. Mineralogical analysis revealed quartz, feldspars, gypsum, and pyrite as the dominant phases. Elevated concentrations of potentially toxic elements, particularly As (4330&#xa0;mg/kg), Pb (3130&#xa0;mg/kg), Zn (6000&#xa0;mg/kg), Cu (1900&#xa0;mg/kg), and Cd (42.5&#xa0;mg/kg), were observed, exceeding regulatory threshold limits for reuse given in Indian standards (MoEF&amp;CC, 2025). Sequential extraction results showed that despite high total metal concentrations, a substantial fraction of metals especially As and Ni was associated with the residual fraction, suggesting limited immediate mobility. In contrast, Zn, Cd, Cu, and Pb exhibited notable proportions in labile fractions, indicating higher environmental sensitivity. Risk index (in particular risk assessment code) identified Zn, Cd, and Pb as priority contaminants, while Ni posed the least risk. Overall, the study highlights the importance of metal speciation-based assessment for sustainable management of gold mine tailings.</p>

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Geoenvironmental characterization and speciation-driven risk assessment of gold mining tailings

  • Ayush Kumar,
  • Mohit Somani,
  • Ahmed Benamar,
  • Syed Hilal Farooq

摘要

The present study investigates the geoenvironmental characteristics and mobility of heavy metals in gold mine tailings collected from a mining region in western India. The tailings were subjected to comprehensive physical, mineralogical, and geochemical characterization, including particle size distribution, XRD-based mineralogy, XRF elemental composition, ICP-OES based total heavy metal analysis, and sequential extraction to evaluate metal speciation and environmental risk. Results indicate that the tailings are fine-grained (< 45 μm) with a slightly alkaline nature. Mineralogical analysis revealed quartz, feldspars, gypsum, and pyrite as the dominant phases. Elevated concentrations of potentially toxic elements, particularly As (4330 mg/kg), Pb (3130 mg/kg), Zn (6000 mg/kg), Cu (1900 mg/kg), and Cd (42.5 mg/kg), were observed, exceeding regulatory threshold limits for reuse given in Indian standards (MoEF&CC, 2025). Sequential extraction results showed that despite high total metal concentrations, a substantial fraction of metals especially As and Ni was associated with the residual fraction, suggesting limited immediate mobility. In contrast, Zn, Cd, Cu, and Pb exhibited notable proportions in labile fractions, indicating higher environmental sensitivity. Risk index (in particular risk assessment code) identified Zn, Cd, and Pb as priority contaminants, while Ni posed the least risk. Overall, the study highlights the importance of metal speciation-based assessment for sustainable management of gold mine tailings.