In mining environmental applications, it is important to assess water quality from waste rock piles (WRPs) and estimate the likelihood of acid rock drainage (ARD) over time. The mineralogical heterogeneity of WRPs is a source of uncertainty in this assessment, undermining the reliability of traditional bulk indicators used in the industry. We focused in this work on the bulk neutralizing potential ratio (NPR), which is defined as the ratio of the content of non-acid-generating minerals (typically reactive carbonates such as calcite) to the content of potentially acid-generating minerals (typically sulfides such as pyrite). We used a streamtube-based Monte-Carlo method to show why and to what extent bulk NPR can be a poor indicator of ARD occurrence. We simulated ensembles of WRPs identical in their geometry and bulk NPR, which only differed in their initial distribution of the acid generating and acid neutralizing minerals that control NPR. All models simulated the same principal acid-producing, acid-neutralizing and secondary mineral forming processes. We show that small differences in the distribution of local NPR values or the number of flow paths that generate acidity strongly influence drainage pH. The results indicate that the likelihood of ARD (epitomized by the probability of occurrence of pH< 4 in a mixing boundary) within the first 100 years can be as high as 75% for a NPR = 2 and 40% for NPR = 4. The latter is traditionally considered as a “universally safe” threshold to ensure non-acidic waters in practical applications. Our results suggest that new methods that explicitly account for mineralogical heterogeneity must be sought when computing effective (upscaled) NPR values at the scale of the piles.

Stochastic multicomponent reactive transport analysis of low quality drainage release from waste rock piles : controls of the spatial distribution of acid generating and neutralizing minerals / D. Pedretti, K.U. Mayer, R.D. Beckie. - In: JOURNAL OF CONTAMINANT HYDROLOGY. - ISSN 0169-7722. - 201(2017), pp. 30-38. [10.1016/j.jconhyd.2017.04.004]

Stochastic multicomponent reactive transport analysis of low quality drainage release from waste rock piles : controls of the spatial distribution of acid generating and neutralizing minerals

D. Pedretti
;
2017

Abstract

In mining environmental applications, it is important to assess water quality from waste rock piles (WRPs) and estimate the likelihood of acid rock drainage (ARD) over time. The mineralogical heterogeneity of WRPs is a source of uncertainty in this assessment, undermining the reliability of traditional bulk indicators used in the industry. We focused in this work on the bulk neutralizing potential ratio (NPR), which is defined as the ratio of the content of non-acid-generating minerals (typically reactive carbonates such as calcite) to the content of potentially acid-generating minerals (typically sulfides such as pyrite). We used a streamtube-based Monte-Carlo method to show why and to what extent bulk NPR can be a poor indicator of ARD occurrence. We simulated ensembles of WRPs identical in their geometry and bulk NPR, which only differed in their initial distribution of the acid generating and acid neutralizing minerals that control NPR. All models simulated the same principal acid-producing, acid-neutralizing and secondary mineral forming processes. We show that small differences in the distribution of local NPR values or the number of flow paths that generate acidity strongly influence drainage pH. The results indicate that the likelihood of ARD (epitomized by the probability of occurrence of pH< 4 in a mixing boundary) within the first 100 years can be as high as 75% for a NPR = 2 and 40% for NPR = 4. The latter is traditionally considered as a “universally safe” threshold to ensure non-acidic waters in practical applications. Our results suggest that new methods that explicitly account for mineralogical heterogeneity must be sought when computing effective (upscaled) NPR values at the scale of the piles.
Acid rock drainage; Mineralogical heterogeneity; Multicomponent reactive transport; Neutralizing potential ratio; Stochastic analysis; Waste rock piles; Carbonates; Groundwater; Hydrogen-Ion Concentration; Iron; Minerals; Monte Carlo Method; Reproducibility of Results; Stochastic Processes; Sulfides; Mining; Models, Theoretical; Environmental Chemistry; Water Science and Technology
Settore GEO/05 - Geologia Applicata
2017
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/2434/624359
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