利用微聚焦x射线荧光、衍射和吸收在蛇纹石(超镁铁)表层土壤中微米尺度上镍的自然形态

IF 0.9 4区 地球科学 Q4 GEOCHEMISTRY & GEOPHYSICS Geochemical Transactions Pub Date : 2018-08-14 DOI:10.1186/s12932-018-0059-2
Matthew G. Siebecker, Rufus L. Chaney, Donald L. Sparks
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引用次数: 12

摘要

蛇形土和超镁铁性红土在超镁铁性基岩上发育,从环境、地球化学和工业的角度来看都是重要的地质物质。它们天然具有较高的微量金属浓度,如镍、铬和钴,以及高水平的铁和镁。矿物质承载这些微量金属并影响金属的流动性。在这些土壤中,镍是一种重要的微量金属,本研究的目的是利用微尺度(μ)技术鉴定含有Ni的天然矿物,并与其他微量金属(如Fe, Mn和Cr)相关。采用同步加速器μ- xrf, μ- xrd和μ- xas。镍常位于蛇纹石矿物的八面体层中,如蜥蜴石,也常位于其他具有类似八面体结构的层状层状层状层状硅酸盐矿物中,如绿泥石群矿物,如斜绿石和绿帘石。镍也存在于针铁矿、赤铁矿、磁铁矿和水合铁中。在微米尺度上,针铁矿与蜥蜴石、反长辉石共存。蜥蜴石在其八面体层中同时整合了Ni和Mn。在微米尺度上,顽辉石、寄生石、闪辉石、绿云母和长石都含有不同数量的Ni和Fe。镍含量增加了6 - 7倍。色辉石和绿云母的μ μ x射线衍射样带。数据显示为8?μm空间尺度。镍与铬铁矿或锌铬铁矿颗粒没有关联。在μ-XRF图中,Ni通常与Fe和Mn相关,而一般与Cr、Zn、Ca或K无关。μ-XAS数据在8400?电动汽车(3.7 ? ?1在k空间)与位于层状层状硅酸盐矿物(如蛇纹石和绿泥石群矿物)的八面体薄片中的Ni高度相关(占平均LCF结果的94%)。将体积- xas LCF与平均μ-XAS LCF结果进行比较,结果表明μ-XAS技术对两种土壤的体积土具有较好的代表性。在μ-XAS分析的位置,平均Ni形态主要是层状层状硅酸盐和蛇纹石矿物(76%),铁氧化物(18%)和锰氧化物(9%)。在μ-XRD分析的位置,平均Ni形态主要由层状层状硅酸盐、蛇纹石和超镁铁质相关矿物(71%)和氧化铁(17%)组成,说明了这两种方法的互补性。
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Natural speciation of nickel at the micrometer scale in serpentine (ultramafic) topsoils using microfocused X-ray fluorescence, diffraction, and absorption

Serpentine soils and ultramafic laterites develop over ultramafic bedrock and are important geological materials from environmental, geochemical, and industrial standpoints. They have naturally elevated concentrations of trace metals, such as Ni, Cr, and Co, and also high levels of Fe and Mg. Minerals host these trace metals and influence metal mobility. Ni in particular is an important trace metal in these soils, and the objective of this research was to use microscale (μ) techniques to identify naturally occurring minerals that contain Ni and Ni correlations with other trace metals, such as Fe, Mn, and Cr. Synchrotron based μ-XRF, μ-XRD, and μ-XAS were used. Ni was often located in the octahedral layer of serpentine minerals, such as lizardite, and in other layered phyllosilicate minerals with similar octahedral structure, such as chlorite group minerals including clinochlore and chamosite. Ni was also present in goethite, hematite, magnetite, and ferrihydrite. Goethite was present with lizardite and antigorite on the micrometer scale. Lizardite integrated both Ni and Mn simultaneously in its octahedral layer. Enstatite, pargasite, chamosite, phlogopite, and forsterite incorporated various amounts of Ni and Fe over the micrometer spatial scale. Ni content increased six to seven times within the same 500?μm μ-XRD transect on chamosite and phlogopite. Data are shown down to an 8?μm spatial scale. Ni was not associated with chromite or zincochromite particles. Ni often correlated with Fe and Mn, and generally did not correlate with Cr, Zn, Ca, or K in μ-XRF maps. A split shoulder feature in the μ-XAS data at 8400?eV (3.7???1 in k-space) is highly correlated (94% of averaged LCF results) to Ni located in the octahedral sheet of layered phyllosilicate minerals, such as serpentine and chlorite-group minerals. A comparison of bulk-XAS LCF to averaged μ-XAS LCF results showed good representation of the bulk soil via the μ-XAS technique for two of the three soils. In the locations analyzed by μ-XAS, average Ni speciation was dominated by layered phyllosilicate and serpentine minerals (76%), iron oxides (18%), and manganese oxides (9%). In the locations analyzed by μ-XRD, average Ni speciation was dominated by layered phyllosilicate, serpentine, and ultramafic-related minerals (71%) and iron oxides (17%), illustrating the complementary nature of these two methods.

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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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