Passive biochemical reactors (PBRs) are a viable alternative to neutralization plants for the treatment of acid mine drainage (AMD) because they require lower investment costs and use residual materials. However, high iron (Fe) concentrations (≥0.5 g/L) in AMD are challenging for their long-term efficiency. Sorption and precipitation are the main Fe removal mechanisms, but the relative importance of each is mostly unknown. In this study, locally available natural materials (organic and inorganic) were characterized and tested for their performance in Fe removal from highly contaminated AMD (pH 3.5, 4 g/L of Fe, and 9 g/L of sulfate). Iron retention capacity of the materials was then evaluated and the efficiency of eight mixtures of materials was compared through 40-day laboratory batch tests. All batch-type PBRs increased the pH up to 6.5 and decreased dissolved metals concentrations, including Fe, up to 99%. Results showed that organic residual materials (manures, municipal wastewater sludge, and compost) were the best substrates for Fe removal.These findings allowed for the selection of three reactive mixtures with distinct characteristics (mixture #1 – 30% organic wastes; mixture #4 – 50% calcite; and mixture #7 – 50% sand) to be further evaluated in column type PBRs.
Iron removal in highly contaminated acid mine drainage using passive biochemical reactors
Thomas Genty, Bruno Bussière, Mostafa Benzaazoua, Carmen M. Neculita, Gérald J. Zagury; Iron removal in highly contaminated acid mine drainage using passive biochemical reactors. Water Sci Technol 9 October 2017; 76 (7): 1833–1843. doi: https://doi.org/10.2166/wst.2017.362
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