Controls of uncertainty in acid rock drainage predictions from waste rock piles examined through Monte-Carlo multicomponent reactive transport

Abstract

Heterogeneity in waste rock piles (WRPs) determines uncertainty in acid mine drainage (ARD) predictions from these deposits. Numerical modeling based on a novel and efficient stochastic framework to evaluate influential heterogeneity-linked factors controlling such uncertainty. The analysis considers a representative WRP with a mean neutralization potential ratio $$\\overline{NPR} = 2$$ NPR ¯ = 2 . The heterogeneity-linked factors are: (1) Scale - dependent mineralogical variability . At the “local” scale, the variability within individual rock blocks in the waste rocks (10\xa0s of cm) is measured through the correlation coefficient ( $$\\rho$$ ρ ) between acid producing and acid consuming minerals, here considered a geogenic property of the site. For the analyzed conditions, as $$\\rho \\to 0$$ ρ → 0 WRPs tend generate a higher risk of ARD and higher variability among results, which can be explained by the increasing mineralogical mixing (blending) as $$\\rho$$ ρ grows. At the “field” scale, the coefficient of variation ( $$CV$$ CV ) is measured as the mineralogical variability of all rock blocks within the WRP. Since $$CV$$ CV is an engineering design parameter of a WRP, the results suggest that building WRPs with lower $$CVs$$ CVs results in less uncertain predictions of long-term neutralization capacity of the piles. (2) Flow heterogeneity . The variance of solute travel times through a pile, here measured by $$\\sigma_{w}^{2}$$ σ w 2 , can be used to characterize flow heterogeneity, where high variance means stronger preferential flow in the WRP. Simulated ARD mass loadings with strong flow heterogeneity ( $$\\sigma_{w}^{2} \\ge 1$$ σ w 2 ≥ 1 ) leads to significant differences to the homogeneous case, increasing the uncertainty in the estimation of the ARD risk. (3) Pore gas concentration . In well-ventilated WRPs the effect of mineralogical heterogeneity is enhanced (WRPs generate much higher risk than WRPs with diffusion-limited gas transport modalities. Gas diffusion limits the amount of acidity produced in sulfidic-rich zones, thus attenuating the effect of mineralogical variability at the scale of the WRPs compared to well-ventilated piles.