AI Article Synopsis
- Red mud (RM) can be an effective, low-cost adsorbent for capturing heavy metals, particularly arsenic during the bio-oxidation of arsenopyrite.
- The study found that adding a small amount of RM (≤ 4 g/L) enhanced bio-oxidation and stabilized arsenic by forming beneficial nanoparticles.
- However, increasing RM to ≥ 6 g/L raised the solution pH, reduced iron bio-oxidation activity, and inhibited arsenopyrite dissolution, blocking arsenic release and indicating potential for RM in reducing arsenic pollution.
Article Abstract
Red mud (RM) as waste of industrial aluminum production is piling up in huge ponds. RM could be a cost-effective adsorbent for heavy metals, but adsorption is vulnerable to pH changes, metal ions speciation and the occurrence of iron bearing minerals. In this study, the precipitation and elemental speciation transformation relevant to arsenic fate in responding to the addition of RM during arsenopyrite bio-oxidation by Sulfobacillus thermosulfidooxidans was investigated. The results show that the addition of RM significantly changed the arsenic precipitation and the solution chemistry and thus affected the arsenopyrite bio-oxidation and arsenic fate. An addition of a small amount (≤ 4 g/L) of RM substantially promoted arsenopyrite bio-oxidation with formation of SiO @ (As, Fe, Al, Si) spherical nanoparticles that can enhance the stability of the immobilized arsenic. The SiO-based spherical nanoparticles precipitate was mainly composed of jarosites, amorphous ferric arsenate and crystalline scorodite, and its formation were controlled by Fe concentration and solution pH. An addition of increased amount of RM (≥ 6 g/L) resulted in a significant increase of the solution pH and a decrease in the Fe bio-oxidation activity, and spherical nanoparticles were not formed. Consequently, the dissolution of arsenopyrite was inhibited and the release of arsenic was blocked. This study suggests the applicability of RM in mitigation of arsenic pollution from bio-oxidation of As-bearing sulfide minerals.
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| http://dx.doi.org/10.1016/j.watres.2021.117539 | DOI Listing |
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Article Synopsis
- Red mud (RM) can be an effective, low-cost adsorbent for capturing heavy metals, particularly arsenic during the bio-oxidation of arsenopyrite.
- The study found that adding a small amount of RM (≤ 4 g/L) enhanced bio-oxidation and stabilized arsenic by forming beneficial nanoparticles.
- However, increasing RM to ≥ 6 g/L raised the solution pH, reduced iron bio-oxidation activity, and inhibited arsenopyrite dissolution, blocking arsenic release and indicating potential for RM in reducing arsenic pollution.
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