含锑的闪长岩转变为网纹石:酸性矿井排水中锑迁移的驱动因素。

Mohammad Rastegari, Niloofar Karimian, Scott G Johnston, Girish Choppala, Mona Hosseinpour Moghaddam, Edward D Burton
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摘要

锑(V)在酸性矿井排水(AMD)中的流动性通常受吸附和与施瓦特曼矿(一种无序的氧化羟基硫酸铁(III)矿物)共沉淀的控制。然而,由于其易变性,随着时间的推移,schwertmannite 会转变为热力学上更稳定的铁(III)相,如鹅卵石。本研究探讨了含Sb(V)的石榴石向鹅绿泥石的转化如何影响Sb(V)的迁移率,同时还评估了Sb(V)在稳定石榴石防止这种转化方面可能发挥的作用。为了实现这些目标,我们让不含 Sb(V)、Sb(V)吸附和 Sb(V)共沉淀的白云母在酸性硫酸盐条件下部分转化为网纹石。铁的 K-edge EXAFS 光谱显示,吸附和共沉淀的 Sb(V) 部分稳定了希沃特曼石,使其免于转化。研究发现,无论 Sb(V)的负载量是多少,也无论 Sb(V)最初是吸附在前驱体石锰矿上还是与前驱体石锰矿共沉淀在一起,石锰矿开始向网纹石转化时都会明显地将 Sb(V)迁移到溶液中。Sb K-edge EXAFS 光谱显示,这一过程涉及将 Sb(V)掺入新形成的网纹石中。我们的研究结果表明,虽然共存的 Sb(V)会部分抑制施瓦格曼矿向网纹石的转化,但这一转化过程的初始阶段会推动 AMD 系统中 Sb(V)的大量迁移。
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Antimony-bearing schwertmannite transformation to goethite: A driver of antimony mobilization in acid mine drainage.

Antimony(V) mobility in acid mine drainage (AMD) is often controlled by sorption and coprecipitation with schwertmannite - a poorly-ordered Fe(III) oxyhydroxysulfate mineral. However, due to its metastable nature, schwertmannite transforms over time to more thermodynamically stable Fe(III) phases, such as goethite. This study examines how transformation of Sb(V)-bearing schwertmannite to goethite impacts Sb(V) mobility, while also assessing the role that Sb(V) may play in stabilizing schwertmannite against such transformation. To address these aims, Sb(V)-free, Sb(V)-sorbed and Sb(V)-coprecipitated schwertmannite were allowed to undergo partial transformation to goethite under acid sulfate conditions. Iron K-edge EXAFS spectroscopy revealed that sorbed and coprecipitated Sb(V) partly stabilized schwertmannite against transformation. The onset of schwertmannite transformation to goethite was found to drive clear mobilization of Sb(V) into solution, regardless of the Sb(V) loading or whether Sb(V) was initially sorbed or coprecipitated with the precursor schwertmannite. This initial phase of Sb(V) mobilization was followed by subsequent solid-phase recapture of the released Sb(V), with Sb K-edge EXAFS spectroscopy revealing that this process involved Sb(V) incorporation into the newly-formed goethite. Our findings show that, although schwertmannite transformation to goethite is partially inhibited by co-existing Sb(V), the initial stage of this transformation process drives significant Sb(V) mobilization in AMD systems.

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