Zn(II) and Cu(II) adsorption and retention onto iron oxyhydroxide nanoparticles: effects of particle aggregation and salinity

IF 0.9 4区 地球科学 Q4 GEOCHEMISTRY & GEOPHYSICS
Rebecca B Chesne, Christopher S Kim
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引用次数: 14

Abstract

Iron oxyhydroxides are commonly found in natural aqueous systems as nanoscale particles, where they can act as effective sorbents for dissolved metals due to their natural surface reactivity, small size and high surface area. These properties make nanoscale iron oxyhydroxides a relevant option for the remediation of water supplies contaminated with dissolved metals. However, natural geochemical processes, such as changes in ionic strength, pH, and temperature, can cause these particles to aggregate, thus affecting their sorption capabilities and remediation potential. Other environmental parameters such as increasing salinity may also impact metal retention, e.g. when particles are transported from freshwater to seawater.

After using synthetic iron oxyhydroxide nanoparticles and nanoparticle aggregates in batch Zn(II) adsorption experiments, the addition of increasing concentrations of chloride (from 0.1 M to 0.6 M) appears to initially reduce Zn(II) retention, likely due to the desorption of outer-sphere zinc surface complexes and subsequent formation of aqueous Zn-Cl complexes, before then promoting Zn(II) retention, possibly through the formation of ternary surface complexes (supported by EXAFS spectroscopy) which stabilize zinc on the surface of the nanoparticles/aggregates. In batch Cu(II) adsorption experiments, Cu(II) retention reaches a maximum at 0.4 M chloride. Copper-chloride surface complexes are not indicated by EXAFS spectroscopy, but there is an increase in the formation of stable aqueous copper-chloride complexes as chloride concentration rises (with CuCl+ becoming dominant in solution at ~0.5 M chloride) that would potentially inhibit further sorption or encourage desorption. Instead, the presence of bidentate edge-sharing and monodentate corner-sharing complexes is supported by EXAFS spectroscopy. Increasing chloride concentration has more of an impact on zinc retention than the mechanism of nanoparticle aggregation, whereas aggregation condition is a stronger determinant of copper retention.

Based on these model uptake/retention studies, iron oxyhydroxide nanoparticles show potential as a strategy to remediate zinc-contaminated waters that migrate towards the ocean. Copper retention, in contrast, appears to be optimized at an intermediate salinity consistent with brackish water, and therefore may release considerable fractions of retained copper at higher (e.g. seawater) salinity levels.

Abstract Image

锌(II)和铜(II)在氢氧化铁纳米颗粒上的吸附和保留:颗粒聚集和盐度的影响
氧化铁通常以纳米级颗粒的形式存在于天然水系统中,由于其天然的表面反应性、小尺寸和高表面积,它们可以作为溶解金属的有效吸附剂。这些特性使纳米级氧化铁成为修复被溶解金属污染的供水系统的相关选择。然而,自然地球化学过程,如离子强度、pH值和温度的变化,会导致这些颗粒聚集,从而影响它们的吸附能力和修复潜力。其他环境参数,如盐度的增加也可能影响金属的滞留,例如当颗粒从淡水输送到海水时。在批量Zn(II)吸附实验中使用合成的氧化铁纳米颗粒和纳米颗粒聚集体后,增加氯离子浓度(从0.1 M到0.6 M)的加入似乎最初降低了Zn(II)的保留,这可能是由于外球面锌表面配合物的解吸和随后形成的水相Zn- cl配合物,然后促进Zn(II)的保留。可能是通过形成三元表面配合物(由EXAFS光谱支持)来稳定纳米颗粒/聚集体表面的锌。在批量Cu(II)吸附实验中,Cu(II)的保留率在0.4 M氯离子处达到最大值。EXAFS光谱没有显示出铜-氯表面配合物,但随着氯浓度的升高(在~0.5 M氯浓度时,溶液中CuCl+占主导地位),稳定的水溶液氯化铜配合物的形成增加,这可能会抑制进一步的吸附或促进解吸。相反,EXAFS光谱支持双齿共边和单齿共角配合物的存在。增加氯离子浓度对锌保留的影响大于纳米颗粒聚集机制,而聚集条件对铜保留的影响更大。基于这些模型吸收/保留研究,氧化铁纳米颗粒显示出修复向海洋迁移的锌污染水域的潜力。相比之下,在与微咸水相一致的中等盐度下,铜的保留似乎是最佳的,因此在较高的盐度(例如海水)水平下,可能会释放出相当一部分保留的铜。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Geochemical Transactions
Geochemical Transactions 地学-地球化学与地球物理
CiteScore
3.70
自引率
4.30%
发文量
2
审稿时长
>12 weeks
期刊介绍: Geochemical Transactions publishes high-quality research in all areas of chemistry as it relates to materials and processes occurring in terrestrial and extraterrestrial systems.
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