Dissolution of Stibnite and Morphological Distribution of Antimony in Its Products under Different Aqueous Conditions
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摘要: 辉锑矿(Sb2S3)的溶解是水环境中锑的重要来源,水中溶解态锑的毒性、迁移性及生物可利用性与其形态密切相关,但当前学界对辉锑矿溶解产物中锑的形态分布的认识并不一致,对于其中锑的特殊形态——硫代锑酸盐的认识的争议尤为突出.鉴于此,我们在不同水环境条件下系统研究了辉锑矿的溶解过程及其对硫代锑酸盐形成的影响,以期为准确评价辉锑矿溶解的环境效应提供依据.结果表明:单一辉锑矿在酸性‒弱碱性条件下的溶解不能形成硫代锑酸盐,在碱性条件下则可形成三硫代锑酸盐和四硫代锑酸盐;在反应系统中总锑含量与天然水中总锑含量相当的情况下,辉锑矿的溶解不可能形成硫代锑酸盐的多聚物.此外,不同类型还原态硫或适量雌黄的共存以及水中离子强度的增加均可促进硫代锑酸盐的形成,过量的雌黄则会抑制其形成.水中S(-Ⅱ)/Sb摩尔比是控制硫代锑酸盐形成的重要因素.在考察天然水环境中辉锑矿淋滤的环境影响以及淋滤过程中硫代锑酸盐的形成潜力时,S(-Ⅱ)/Sb摩尔比是应重点参考的关键指标.Abstract: The dissolution of stibnite (Sb2S3) is an important source of antimony in the aqueous environment, and the toxicity, mobility and bioavailability of dissolved antimony in water are closely related to its morphology, but the current understanding of the morphological distribution of antimony in the dissolution products of stibnite is not consistent, and the understanding of the particular form of antimony, thioantimonate, is particularly controversial. In this context, it systematically investigated the dissolution process of stibnite and its effect on the formation of thioantimonate under different aqueous conditions, to provide a basis for the accurate evaluation of the environmental effects of stibnite dissolution. The results show that the dissolution of stibnite under acidic-weak alkaline conditions does not lead to the formation of thioantimonate, while under alkaline conditions trithioantimonate and tetrathioantimonate can be formed; the dissolution of stibnite is unlikely to lead to the formation of poly-thioantimonate when the initial total antimony content in the reaction system is comparable to that in natural water. In addition, the coexistence of different types of reduced sulfur or moderate amounts of orpiment and an increase in the ionic strength of the water can promote the formation of thioantimonate, which is inhibited by excess orpiment. The S(-Ⅱ)/Sb molar ratio in water is an important factor in controlling the formation of thioantimonate; the S(-Ⅱ)/Sb molar ratio is a key indicator to be considered when examining the environmental impact of stibnite leaching in natural water environments and the potential for thioantimonate formation during leaching.
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图 1 不同pH值条件下辉锑矿溶解过程中关键水化学参数和溶解产物随时间的变化
a. pH值变化;b.总锑浓度,(pH=3、5、7、9);c.总锑浓度(pH=11);d.硫化物浓度;e.硫酸盐浓度;f.硫代硫酸盐浓度
Fig. 1. Changes over time in critical hydrochemical parameters and dissolved products during the dissolution of stibnite at different pHs
图 2 有氧和厌氧环境中不同pH(3‒11)条件下对辉锑矿溶解和硫代锑酸盐形成的影响
a.反应6 h时淋滤液中锑形态分布;b.反应720 h时淋滤液中锑形态分布;c.有氧条件下硫代锑酸盐形态占总锑比例随时间变化;d.厌氧条件下硫代锑酸盐形态占总锑比例随时间变化;e.有氧条件下硫代锑酸盐浓度随时间的变化;f.厌氧条件下硫代锑酸盐浓度随时间的变化
Fig. 2. Effect of different pH (3‒11) conditions on stibnite dissolution and thioantimonate formation in aerobic and anaerobic environments
图 3 不同As2S3/Sb2S3摩尔比条件下雌黄对辉锑矿溶解和硫代锑酸盐形成的影响
a.锑形态分布;b.砷形态分布. 反应时间均为168 h;溶液初始pH值均为11
Fig. 3. Effect of orpiment on the dissolution of stibnite and the formation of thioantimonates under different As2S3/Sb2S3 molar ratios
图 4 不同类型还原态硫与之共存对辉锑矿溶解和硫代锑酸盐形成的影响
Fig. 4. Effect of the co-presence of different forms of reductive sulfur on the dissolution of stibinte and the formation of thioantimonates
图 5 不同离子强度条件下硫代锑酸盐在总锑中占比随时间的变化(a), S(-Ⅱ)/Sb摩尔比随时间的变化(b), 辉锑矿溶解6 h、168 h后淋滤液中锑形态分布的变化(c)
Fig. 5. The changes in the proportion of thioantimonate in total antimony over time (a), the changes in S(-Ⅱ)/Sb molar ratio with time (b) and the changes in the morphological distribution of antimony in solution after 6 h and 168 h of dissolution of stibnite under different ionic strength conditions(c)
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