腐殖物质对氧化铝和粘土吸附铁(II)的影响

IF 0.9 4区 地球科学 Q4 GEOCHEMISTRY & GEOPHYSICS
Ying Zhu, Jingjing Liu, Omanjana Goswami, Ashaki A. Rouff, Evert J. Elzinga
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引用次数: 12

摘要

采用间歇动力学实验和同步加速器Fe K-edge EXAFS分析相结合的方法,研究了pH为7.5时腐殖质(HS)对Al-oxide和clay吸附剂对Fe(II)吸附的影响。在4个小时内监测铁(II)吸附。添加不同HS类型(腐植酸、透明质酸)的缺氧粘土和氧化铝悬浮液;或黄腐酸,FA)和水平(0、1和4 wt%),以及不同的Fe(II)和HS添加顺序(共吸附和预涂覆实验,其中Fe(II)山梨酸盐分别与HS添加一起和之后添加)。在Al-oxide悬浮液中,HS的存在减缓了Fe(II)的吸附动力学,但对水中平衡Fe(II)浓度的影响有限(如果有的话)。EXAFS分析显示,在含ha和不含ha体系中,Fe(II) -Al (III)-层状双氢氧化物(LDH)相的析出是Fe(II)吸附的主要模式。这些结果表明,HS减缓了al -氧化物悬浮液中Fe(II)的析出,但不影响形成的Fe(II) -Al (III)-LDH次级相的组成和稳定性。HS对Fe(II) -Al (III)-LDH沉淀的干扰是由于形成有机Al配合物HS限制了Al融入二级层状Fe(II)-氢氧化物的可用性。在粘土体系中,HA的存在导致主要的Fe(II)吸附产物从Fe(II) -Al (III)-LDH转变为含有少量结构Al的Fe(II)-叶状硅酸盐。这是由于HA对Al的络合作用,再加上粘土悬浮液中溶解的Si的存在,使得叶状硅酸盐沉淀。在较低HA水平下,Fe(II)沉淀机制的变化不影响Fe(II)的吸附速率,表明该体系中Fe(II) -Al (III)-LDH形成的抑制作用被增强的Fe(II)-phyllosilicate沉淀所抵消。在较高的HA水平下,Fe(II)吸附速率的降低归因于HA对粘土表面或其附近生长的次生Fe(II)矿物的表面遮蔽或中毒。研究结果表明,HS在还原性土壤中对Fe(II)沉淀的动力学和产物起着重要的控制作用,其作用受土壤矿物学、HS含量和HS性质的调节。需要进一步的工作来评估层状铁(II)氢氧化物在自然还原环境中的重要性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Effects of humic substances on Fe(II) sorption onto aluminum oxide and clay

Effects of humic substances on Fe(II) sorption onto aluminum oxide and clay

We studied the effects of humic substances (HS) on the sorption of Fe(II) onto Al-oxide and clay sorbents at pH 7.5 with a combination of batch kinetic experiments and synchrotron Fe K-edge EXAFS analyses. Fe(II) sorption was monitored over the course of 4?months in anoxic clay and Al-oxide suspensions amended with variable HS types (humic acid, HA; or fulvic acid, FA) and levels (0, 1, and 4 wt%), and with differing Fe(II) and HS addition sequences (co-sorption and pre-coated experiments, where Fe(II) sorbate was added alongside and after HS addition, respectively). In the Al-oxide suspensions, the presence of HS slowed down the kinetics of Fe(II) sorption, but had limited, if any, effect on the equilibrium aqueous Fe(II) concentrations. EXAFS analyses revealed precipitation of Fe(II)–Al(III)-layered double hydroxide (LDH) phases as the main mode of Fe(II) sorption in both the HA-containing and HA-free systems. These results demonstrate that HS slow down Fe(II) precipitation in the Al-oxide suspensions, but do not affect the composition or stability of the secondary Fe(II)–Al(III)-LDH phases formed. Interference of HS with the precipitation of Fe(II)–Al(III)-LDH was attributed to the formation organo-Al complexes HS limiting the availability of Al for incorporation into secondary layered Fe(II)-hydroxides. In the clay systems, the presence of HA caused a change in the main Fe(II) sorption product from Fe(II)–Al(III)-LDH to a Fe(II)-phyllosilicate containing little structural Al. This was attributed to complexation of Al by HA, in combination with the presence of dissolved Si in the clay suspension enabling phyllosilicate precipitation. The change in Fe(II) precipitation mechanism did not affect the rate of Fe(II) sorption at the lower HA level, suggesting that the inhibition of Fe(II)–Al(III)-LDH formation in this system was countered by enhanced Fe(II)-phyllosilicate precipitation. Reduced rates of Fe(II) sorption at the higher HA level were attributed to surface masking or poisoning by HA of secondary Fe(II) mineral growth at or near the clay surface. Our results suggest that HS play an important role in controlling the kinetics and products of Fe(II) precipitation in reducing soils, with effects modulated by soil mineralogy, HS content, and HS properties. Further work is needed to assess the importance of layered Fe(II) hydroxides in natural reducing environments.

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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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