云南宝山地区不同母质土壤稀土元素地球化学特征

IF 1 4区地球科学 Q3 GEOCHEMISTRY & GEOPHYSICS

Geochemistry-Exploration Environment Analysis Pub Date : 2021-02-16 DOI:10.1144/geochem2019-082

Li Zhang, Wei Han, M. Peng, Fei Liu, Yuntao Song, Xiu-jin Liu, Qiaolin Wang, Kuo Li, Dongjie Zhao, Wei Yang, Y. Qin, Hangxin Cheng

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引用次数: 3

摘要

为了更好地了解云南宝山地区不同母质风化过程中稀土元素的富集、分布及其特征，研究了寄主地层岩石样品、两个矿床(合桃坪铜铅锌矿:HTP和黑岩脑铁铜铅锌矿:HYA)矿石样品以及上覆或附近土壤中稀土元素的地球化学特征。泥岩和砂岩组总REE (ΣREE)含量最高。岩石和矿石的球粒陨石归一化图显示出明显的轻稀土(lree)富集和Eu耗尽(HYA中的矿石除外)。铈在碳酸盐岩(Є-3-R, C-R, D-R, T-1-R和T-2-R)中表现出明显的负异常。碳酸盐岩(T-1-S、C-S和Є-3-S)上覆土壤ΣREE含量最高，玄武岩上覆土壤ΣREE含量最低。土壤中lree富集，Eu负异常，Ce轻微异常。土壤具有较高的∑LREE/∑heavy REE (HREE)值可能是有机质优先吸收LREE的结果。研究区缺乏长石的母质土壤，特别是碳酸盐发育的土壤，出现负Eu异常。与母质相比，大多数土壤表现出REE富集，因为碱金属被去除，REE在表面过程中被低迁移率富集，而其他三价稀土的风化溶解则表现出正的Ce异常，其离子半径与Ca2+相似。补充资料:其他数据(表S1和S2)和样本位置(图S1)可在https://doi.org/10.6084/m9.figshare.c.5303140上获得

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Geochemical characteristics of rare earth elements (REEs) in soils developed on different parent materials, in the Baoshan area, Yunnan Province, SW China

The geochemistry of rare earth elements (REEs) was studied in rock samples from host formations, ore samples from two mineral deposits (the Hetaoping Cu-Pb-Zn mine: HTP and the Heiyanao Fe-Cu-Pb-Zn mine: HYA) and the overlying or nearby soils to better understand REE concentrations, distributions and behaviour during weathering from different parent materials at the regional scale, Baoshan area, Yunnan Province, SW China. The mudstone and sandstone formations have the highest total REE (ΣREE) contents. Chondrite-normalized diagrams for rocks and ores show significant light REEs (LREEs) enrichments and Eu depletion (except for ores in HYA). Cerium displays an obvious negative anomaly in carbonate rocks (Є-3-R, C-R, D-R, T-1-R and T-2-R). Soils overlying carbonate rock formations (T-1-S, C-S and Є-3-S) have the highest ΣREE contents, while soils overlying basalts have the lowest ΣREE contents. Soils show enrichments in LREEs with negative Eu anomalies and slight Ce anomalies in the studied soils. Soils with high ∑LREE/∑heavy REE (HREE) values may result from the preferential absorption of LREEs by organic matter. Negative Eu anomalies in soils occur for parent materials in the study area lacking feldspar, especially soils developed from carbonates. Compared to the parent materials, most soils show REE enrichment because alkali metals are removed and REEs are concentrated by low mobility in surficial processes and positive Ce anomalies because of weathering dissolution of other trivalent REEs with ionic radii similar to that of Ca2+. Supplementary material: Additional data (Tables S1 and S2) and sample locations (Fig. S1) are available at https://doi.org/10.6084/m9.figshare.c.5303140

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来源期刊

Geochemistry-Exploration Environment Analysis 地学-地球化学与地球物理

CiteScore

3.60

自引率

16.70%

发文量

审稿时长

1 months

期刊介绍： Geochemistry: Exploration, Environment, Analysis (GEEA) is a co-owned journal of the Geological Society of London and the Association of Applied Geochemists (AAG). GEEA focuses on mineral exploration using geochemistry; related fields also covered include geoanalysis, the development of methods and techniques used to analyse geochemical materials such as rocks, soils, sediments, waters and vegetation, and environmental issues associated with mining and source apportionment. GEEA is well-known for its thematic sets on hot topics and regularly publishes papers from the biennial International Applied Geochemistry Symposium (IAGS). Papers that seek to integrate geological, geochemical and geophysical methods of exploration are particularly welcome, as are those that concern geochemical mapping and those that comprise case histories. Given the many links between exploration and environmental geochemistry, the journal encourages the exchange of concepts and data; in particular, to differentiate various sources of elements. GEEA publishes research articles; discussion papers; book reviews; editorial content and thematic sets.