华北大地电磁测深阵列观测实验与岩石圈导电性快速成像模型

OURO-DJOBO SEDIKOU B., 魏文博, 叶高峰, 金胜, 景建恩, 姬磊喆, 董浩, 张乐天, 尹曜田, 谢成良. 2018. 华北大地电磁测深阵列观测实验与岩石圈导电性快速成像模型. 地球物理学报, 61(6): 2508-2524, doi: 10.6038/cjg2018L0695
引用本文: OURO-DJOBO SEDIKOU B., 魏文博, 叶高峰, 金胜, 景建恩, 姬磊喆, 董浩, 张乐天, 尹曜田, 谢成良. 2018. 华北大地电磁测深阵列观测实验与岩石圈导电性快速成像模型. 地球物理学报, 61(6): 2508-2524, doi: 10.6038/cjg2018L0695
OURO-DJOBO SEDIKOU B., WEI WenBo, YE GaoFeng, JIN Sheng, JING JianEn, JI LeiZhe, DONG Hao, ZHANG LeTian, YIN YaoTian, XIE ChengLiang. 2018. Experiments of magnetotelluric observation network on North China and lithospheric conductivity structure from fast imaging method. Chinese Journal of Geophysics (in Chinese), 61(6): 2508-2524, doi: 10.6038/cjg2018L0695
Citation: OURO-DJOBO SEDIKOU B., WEI WenBo, YE GaoFeng, JIN Sheng, JING JianEn, JI LeiZhe, DONG Hao, ZHANG LeTian, YIN YaoTian, XIE ChengLiang. 2018. Experiments of magnetotelluric observation network on North China and lithospheric conductivity structure from fast imaging method. Chinese Journal of Geophysics (in Chinese), 61(6): 2508-2524, doi: 10.6038/cjg2018L0695

华北大地电磁测深阵列观测实验与岩石圈导电性快速成像模型

  • 基金项目:

    国家深部探测技术与实验研究(SinoProbe)专项下属大陆电磁参数标准网实验研究(SinoProbe-01)项目资助

详细信息
    作者简介:

    OURO-DJOBO SEDIKOU B, 男, 1982年出生, 多哥人, 留学生, 博士研究生, 主要从事大地电磁测深方法技术和应用研究.E-mail:osebil81@yahoo.fr

    通讯作者: 魏文博, 男, 1945年出生, 教授, 主要从事电磁探测方法理论和地球深部结构与动力学过程教学及研究.E-mail:wwb5130@cugb.edu.cn
  • 中图分类号: P317;P318

Experiments of magnetotelluric observation network on North China and lithospheric conductivity structure from fast imaging method

More Information
  • 关于中国大陆岩石圈导电性结构研究越来越引起人们的重视,而目前研究大陆岩石圈导电性结构的主要方法是大地电磁测深(Magnetotelluric sounding).为此,在国家项目"深部探测技术与实验研究(SinoProbe)"专项里开展了"大陆电磁参数标准网实验(SinoProbe-01)"研究,完成了华北1°×1°地理坐标网度的大地电磁测深"标准点"阵列(Array)观测.本文详细论述了华北SinoProbe-01项目1°×1°MT"标准点"阵列观测实验的概况,以及通过精细的MT数据处理和一维Niblett-Bostick变换快速成像,所获取的华北地区岩石圈导电性三维成像模型.在分析华北岩石圈导电性结构特征的基础上,从电性结构角度把华北与邻区岩石圈划分为胶辽、燕山、鲁西、太行—吕梁等低导电性(高电阻率)块体,内蒙古、阿拉善和祁连中等导电性块体和黄淮、鄂尔多斯、秦岭良导电性(低电阻率)块体,进一步从导电性的角度证实了华北克拉通是由多个块体集合而成的观点.

  • 加载中
  • 图 1 

    SinoProbe-MT华北阵列观测网

    Figure 1. 

    SinoProbe-MT array observation of North China

    图 2 

    SinoProbe-MT阵列观测网布置示意图

    Figure 2. 

    Schematic diagram of the SinoProbe-MT array observation network

    图 3 

    MT测站布设示意图

    Figure 3. 

    Observation system of MT data

    图 4 

    超宽频带MT测深曲线

    Figure 4. 

    Ultra-broadband MT sounding curve

    图 5 

    华北1°×1°MT阵列观测网10839号中心测站及辅助测站宽频大地电磁测深曲线

    Figure 5. 

    Apparent resistivity and phase curves of the 10839 central station and its auxiliaries stations belonging to the North China 1°×1° MT array

    图 6 

    SinoProbe-MT华北阵列观测网大地电磁测深数据质量分布图

    Figure 6. 

    The data quality classification map of the North China SinoProbe-MT observation network

    图 7 

    华北地区地壳等厚度图(He et al., 2013)

    Figure 7. 

    Crustal thickness contour map of the North China Craton (He et al., 2013)

    图 8 

    华北研究区MT视电阻率频率响应结构图

    Figure 8. 

    Apparent resistivity map of the North China at different frequency

    图 9 

    华北大地电磁测深阵列观测网2000 s信号理论探测深度分布图

    Figure 9. 

    Theorical penetrating depths of the 2000 s magnetotelluric signals of the North China Sinoprobe MT array

    图 10 

    “棋盘格”模型测试一维N-B变换电阻率最大值快速成像

    Figure 10. 

    "Checkerboard" model tests for the 1-D N-B fast resistivity imaging

    图 11 

    华北N-B变换岩石圈三维导电性结构图

    Figure 11. 

    Three-dimensional conductivity Structure of North China lithosphere using N-B transform

    图 12 

    华北地区地形图

    Figure 12. 

    Topographic map of North China

    图 13 

    华北构造分区略图(Zhao et al., 1998, 2001)

    Figure 13. 

    The North China tectonic map (Zhao et al., 1998, 2001)

    图 14 

    由岩石圈电性结构划分的华北及其邻区构造格局

    Figure 14. 

    Tectonic framework of North China and adjacent areas divided based on the lithospheric electrical structure

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出版历程
收稿日期:  2017-11-01
修回日期:  2018-03-11
上线日期:  2018-06-05

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