中国西南地区大面积稀土异常区稀土来源
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摘要
中国贵州、云南和广西交界处存在大面积以宣威地区为中心的土壤稀土元素地球化学异常,为了探究该地区土壤稀土元素来源,本研究采集了宣威地区土壤(红土)和岩石(玄武岩、白云岩、灰岩、砂岩、粉砂岩、泥岩、凝灰岩和页岩)样品,分析了稀土元素、微量元素、pH值和有机质组成。结果显示:土壤稀土元素含量均在大陆上地壳的2倍左右,玄武岩稀土元素含量与上覆土壤一致,但沉积岩(白云岩、石灰岩和砂岩)稀土元素含量远低于上覆土壤。土壤稀土元素与基性岩中富集的元素Co、Ni、Cu、Zn和Au等具有极好的相关性(相关系数r>0.7),但与pH值(r=0.33)和有机质含量(r=0.20)无明显相关关系。玄武岩与其上覆土壤之间的稀土配分模式具有高度的一致性,而沉积岩与其上覆土壤之间的稀土配分模式差异较大,且所有土壤中位值的稀土配分模式与玄武岩的极其相似。宣威地区处于既有玄武岩又有海相沉积岩出露的区域,玄武岩可能是该地区土壤稀土元素的主要来源。
There is a large REE soil geochemical anomaly, which is centered in the Xuanwei area, in the conjunction area of Guizhou, Yunnan, and Guangxi provinces, China. In this study, soil(red clay) and various kinds of rocks(basalt, dolomite, limestone, sandstone, siltstone, mudstone, tuff, and shale) in the Xuanwei area have been collected for analyzing contents of the REE and trace elements, and organic matter(Corg) composition, and measuring pH values in order to explore the REE source of soils in the area. The results show that the REE content of soils are about two times higher than that of the upper continental crust. The REE contents of basalt samples are consistent with those of the overlying soils, but the REE contents of sedimentary rocks(dolomite, limestone, and sandstone)are far below those of the overlying soils. The REE contents of the soil samples have excellent correlation(r > 0.7)with their contents of Co, Ni, Cu, Zn, and Au, which are normally rich in basic rocks, but have no obvious correlations with pH values(r=0.33) and organic matter contents(r=0.20). The REE distribution patterns of basalts are highly consistent with those of the overlying soils, while REE patterns of sedimentary rocks are quite different to those of the overlying soils. In addition, the REE pattern of median values of all soil samples is exactly similar with that of the basalt. Although basalt and marine sedimentary rocks are both exposed in the Xuanwei area, the basalt may be the main source of REE in soil samples in the REE geochemical anomaly area.
There is a large REE soil geochemical anomaly, which is centered in the Xuanwei area, in the conjunction area of Guizhou, Yunnan, and Guangxi provinces, China. In this study, soil(red clay) and various kinds of rocks(basalt, dolomite, limestone, sandstone, siltstone, mudstone, tuff, and shale) in the Xuanwei area have been collected for analyzing contents of the REE and trace elements, and organic matter(Corg) composition, and measuring pH values in order to explore the REE source of soils in the area. The results show that the REE content of soils are about two times higher than that of the upper continental crust. The REE contents of basalt samples are consistent with those of the overlying soils, but the REE contents of sedimentary rocks(dolomite, limestone, and sandstone)are far below those of the overlying soils. The REE contents of the soil samples have excellent correlation(r > 0.7)with their contents of Co, Ni, Cu, Zn, and Au, which are normally rich in basic rocks, but have no obvious correlations with pH values(r=0.33) and organic matter contents(r=0.20). The REE distribution patterns of basalts are highly consistent with those of the overlying soils, while REE patterns of sedimentary rocks are quite different to those of the overlying soils. In addition, the REE pattern of median values of all soil samples is exactly similar with that of the basalt. Although basalt and marine sedimentary rocks are both exposed in the Xuanwei area, the basalt may be the main source of REE in soil samples in the REE geochemical anomaly area.
引文
[1] Verplanck P L. The Role of Fluids in the Formation of Rare Earth Element Deposits[J]. Procedia Earth and Planetary Science, 2017, 17:758-761.
[2]佘海东,范宏瑞,胡芳芳,等.稀土元素在热液中的迁移与沉淀[J].岩石学报, 2018, 34(12):3567-3581.
[3]程志中,谢学锦,冯济舟,等.中国南方地区地球化学图集[M].北京:地质出版社, 2014.
[4]杨瑞东,鲍淼,廖琍,等.贵州西部中、上二叠统界线附近风化壳类型及成矿作用[J].矿物学报, 2007, 27(1):41-48.
[5]黄训华.威宁鹿房稀土矿地质特征及成矿作用初步分析[J].贵州地质, 1997(4):328-333.
[6]王伟.贵州西部二叠系玄武岩风化壳及其中稀土富集规律研究[D].贵阳:贵州大学, 2008.
[7]陈智,郑禄林,陈军,等.贵州威宁玉龙铌矿稀土富集层的发现及其成矿意义[J].稀土, 2017(6):117-124.
[8]姜永果,郭欣,周洪瑞,等.云南曲靖地区下寒武统黑色岩系岩石地球化学特征与成因[J].矿物学报, 2015, 35(4):489-496.
[9]徐东.滇东曲靖地区黑色岩系成矿地质特征及找矿方向[J].云南地质, 2017, 36(2):181-185.
[10]贵州省地质矿产局.贵州省区域地质志[M].北京:地质出版社, 1987.
[11]云南省地质矿产局.云南省区域地质志[M].北京:地质出版社, 1990.
[12] Su W, Dong W, Zhang X, et al. Carlin-Type Gold Deposits in the Dian-Qian-Gui “Golden Triangle” of Southwest China[J]. Reviews in Economic Geology, 2018, 20:157-185.
[13]谭亲平.黔西南水银洞卡林型金矿构造地球化学及成矿机制研究[D].北京:中国科学院大学, 2015.
[14] Fan W, Zhang C, Wang Y, et al. Geochronology and geochemistry of Permian basalts in western Guangxi Province, Southwest China:Evidence for plume-lithosphere interaction[J]. Lithos, 2008, 102(1):218-236.
[15]张勤,白金峰,王烨.地壳全元素配套分析方案及分析质量监控系统[J].地学前缘, 2012, 19(3):33-42.
[16]王学求,周建,徐善法,等.全国地球化学基准网建立与土壤地球化学基准值特征[J].中国地质, 2016, 43(5):1469-1480.
[17] Wang X. China geochemical baselines:Sampling methodology[J]. Journal of Geochemical Exploration, 2015, 148:25-39.
[18] Rudnick R L, Gao S. Composition of the continental crust[G]//Holland H D, Turekian K. Treatise on geochemistry. ELSEVIER, 2014, 4:1-51.
[19]胡璇,石磊.赤泥中稀土元素的主成分分析和聚类分析[J].中国稀土学报, 2017, 35(5):667-671.
[20]刘英俊,曹励明,李兆麟,等.元素地球化学[M].北京:科学出版社, 1984:1-548.
[21]陈炳辉,韦慧晓,黄志国,等.表生地质体的Ce异常及其影响因素综述[J].稀土, 2007, 28(4):79-83.
[2]佘海东,范宏瑞,胡芳芳,等.稀土元素在热液中的迁移与沉淀[J].岩石学报, 2018, 34(12):3567-3581.
[3]程志中,谢学锦,冯济舟,等.中国南方地区地球化学图集[M].北京:地质出版社, 2014.
[4]杨瑞东,鲍淼,廖琍,等.贵州西部中、上二叠统界线附近风化壳类型及成矿作用[J].矿物学报, 2007, 27(1):41-48.
[5]黄训华.威宁鹿房稀土矿地质特征及成矿作用初步分析[J].贵州地质, 1997(4):328-333.
[6]王伟.贵州西部二叠系玄武岩风化壳及其中稀土富集规律研究[D].贵阳:贵州大学, 2008.
[7]陈智,郑禄林,陈军,等.贵州威宁玉龙铌矿稀土富集层的发现及其成矿意义[J].稀土, 2017(6):117-124.
[8]姜永果,郭欣,周洪瑞,等.云南曲靖地区下寒武统黑色岩系岩石地球化学特征与成因[J].矿物学报, 2015, 35(4):489-496.
[9]徐东.滇东曲靖地区黑色岩系成矿地质特征及找矿方向[J].云南地质, 2017, 36(2):181-185.
[10]贵州省地质矿产局.贵州省区域地质志[M].北京:地质出版社, 1987.
[11]云南省地质矿产局.云南省区域地质志[M].北京:地质出版社, 1990.
[12] Su W, Dong W, Zhang X, et al. Carlin-Type Gold Deposits in the Dian-Qian-Gui “Golden Triangle” of Southwest China[J]. Reviews in Economic Geology, 2018, 20:157-185.
[13]谭亲平.黔西南水银洞卡林型金矿构造地球化学及成矿机制研究[D].北京:中国科学院大学, 2015.
[14] Fan W, Zhang C, Wang Y, et al. Geochronology and geochemistry of Permian basalts in western Guangxi Province, Southwest China:Evidence for plume-lithosphere interaction[J]. Lithos, 2008, 102(1):218-236.
[15]张勤,白金峰,王烨.地壳全元素配套分析方案及分析质量监控系统[J].地学前缘, 2012, 19(3):33-42.
[16]王学求,周建,徐善法,等.全国地球化学基准网建立与土壤地球化学基准值特征[J].中国地质, 2016, 43(5):1469-1480.
[17] Wang X. China geochemical baselines:Sampling methodology[J]. Journal of Geochemical Exploration, 2015, 148:25-39.
[18] Rudnick R L, Gao S. Composition of the continental crust[G]//Holland H D, Turekian K. Treatise on geochemistry. ELSEVIER, 2014, 4:1-51.
[19]胡璇,石磊.赤泥中稀土元素的主成分分析和聚类分析[J].中国稀土学报, 2017, 35(5):667-671.
[20]刘英俊,曹励明,李兆麟,等.元素地球化学[M].北京:科学出版社, 1984:1-548.
[21]陈炳辉,韦慧晓,黄志国,等.表生地质体的Ce异常及其影响因素综述[J].稀土, 2007, 28(4):79-83.
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