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    老挝表层沉积物69种元素地球化学背景值

    王玮 王学求 张必敏 聂兰仕 程新彬 韩志轩 刘汉粮 刘东盛

    王玮, 王学求, 张必敏, 聂兰仕, 程新彬, 韩志轩, 刘汉粮, 刘东盛, 2022. 老挝表层沉积物69种元素地球化学背景值. 地球科学, 47(8): 2765-2780. doi: 10.3799/dqkx.2021.151
    引用本文: 王玮, 王学求, 张必敏, 聂兰仕, 程新彬, 韩志轩, 刘汉粮, 刘东盛, 2022. 老挝表层沉积物69种元素地球化学背景值. 地球科学, 47(8): 2765-2780. doi: 10.3799/dqkx.2021.151
    Wang Wei, Wang Xueqiu, Zhang Bimin, Nie Lanshi, Cheng Xinbin, Han Zhixuan, Liu Hanliang, Liu Dongsheng, 2022. Geochemical Background Values of 69 Elements in Surface Sediment of the Laos. Earth Science, 47(8): 2765-2780. doi: 10.3799/dqkx.2021.151
    Citation: Wang Wei, Wang Xueqiu, Zhang Bimin, Nie Lanshi, Cheng Xinbin, Han Zhixuan, Liu Hanliang, Liu Dongsheng, 2022. Geochemical Background Values of 69 Elements in Surface Sediment of the Laos. Earth Science, 47(8): 2765-2780. doi: 10.3799/dqkx.2021.151

    老挝表层沉积物69种元素地球化学背景值

    doi: 10.3799/dqkx.2021.151
    基金项目: 

    国家重点研发计划项目 2016YFC0600600

    中国地质调查项目 DD20190451

    中国地质调查项目 DD20221807

    物化探所中央级公益性科研院所基本科研业务费专项资金资助项目 AS2022P03

    详细信息
      作者简介:

      王玮(1984-),女,硕士,高级工程师,从事勘查地球化学研究. ORCID:0000-0002-0040-609X.E-mail:cgswangwei@163.com

      通讯作者:

      王学求, E-mail:wxueqiu@mail.cgs.gov.cn

    • 中图分类号: P595;P596

    Geochemical Background Values of 69 Elements in Surface Sediment of the Laos

    • 摘要: 老挝地质条件优越,资源潜力巨大. 为响应国家“一带一路”倡议,在老挝全境开展1∶100万国家尺度地球化学填图工作. 采集了大量地球化学数据,为研究区元素分散富集、矿产开发、环境保护、农业生产提供了高质量的基础地球化学数据.共采集地球化学样品2 079件,采用高精度分析技术及严格的质量控制,分析了69种元素. 采用X±3S一次性剔除异点后数据集的中位值作为估值,首次给出了老挝全国69种元素地球化学背景值,填补了老挝国家尺度地球化学填图工作的空白. 初步讨论了老挝全境、7个三级大地构造单元,6个三级成矿带69种元素的背景值特征. 研究表明不同构造单元中受地质背景、构造及岩浆活动的影响,元素分布具有各自特征,同时不同成矿带受成矿作用及构造岩浆活动的影响,元素在各个成矿带分布特征不同,元素的富集对矿床有很好的指示意义. 这些背景值的获得为下一步深入研究老挝地球化学填图数据提供了基础对比数据.

       

    • 图  1  采样点位及统计单元图

      刘书生等(2018)王宏等(2015)修改

      Fig.  1.  Skech map of the sampling sites and statistic units

      图  2  景洪-素可泰火山弧区域浓集系数对比图

      Fig.  2.  Comparison map of regional concentration coefficient values in Jinghong⁃Sukhothai arc

      图  3  思茅-彭世洛区域浓集系数对比图

      Fig.  3.  Comparison map of regional concentration coefficient values in Simao⁃Phitsanulok block

      图  4  奠边府-黎府缝合带区域浓集系数对比图

      Fig.  4.  Comparison map of regional concentration coefficient values in DienBienPhu⁃Loei suture

      图  5  万象-昆嵩地块区域浓集系数对比图

      Fig.  5.  Comparison map of regional concentration coefficient values in Vientiane⁃Kontum block

      图  6  色潘-三岐缝合带区域浓集系数对比图

      Fig.  6.  Comparison map of regional concentration coefficient values in Sepon⁃TamKy suture

      图  7  长山地块区域浓集系数对比图

      Fig.  7.  Comparison map of regional concentration coefficient values in Truong Son block

      图  8  哀牢山-马江缝合带区域浓集系数对比图

      Fig.  8.  Comparison map of regional concentration coefficient values in Ailaoshan⁃Song Ma sture

      图  9  清迈成矿带区域浓集系数对比图

      Fig.  9.  Comparison map of regional concentration coefficient values in Chiang Mai Metallogenic Belt

      图  10  琅南塔-庄他武里成矿带区域浓集系数对比图

      Fig.  10.  Comparison map of regional concentration coefficient values in Luangnamtha⁃Chanthaburi Metallogenic Belt

      图  11  琅勃拉邦-大叻成矿带区域浓集系数对比图

      Fig.  11.  Comparison map of regional concentration coefficient values in Louangphrabang⁃Đà Lat Metallogenic Belt

      图  12  万象-昆嵩成矿带区域浓集系数对比图

      Fig.  12.  Comparison map of regional concentration coefficient values in Vientiane⁃Kontum Metallogenic Belt

      图  13  长山成矿带区域浓集系数对比图

      Fig.  13.  Comparison map of regional concentration coefficient values in Truong Son Metallogenic Belt

      图  14  红河成矿带区域浓集系数对比图

      Fig.  14.  Comparison map of regional concentration coefficient values in Honghe Metallogenic Belt

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    • 收稿日期:  2021-08-26
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