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利用古地磁学方法恢复钻孔岩心原始方位可靠性的探讨:以塔里木盆地钻井为例

谌微微 杨风丽 庄圆 徐铭辰 胡虞杨

谌微微, 杨风丽, 庄圆, 徐铭辰, 胡虞杨. 利用古地磁学方法恢复钻孔岩心原始方位可靠性的探讨:以塔里木盆地钻井为例[J]. 地质科技通报, 2023, 42(6): 266-280. doi: 10.19509/j.cnki.dzkq.tb20220255
引用本文: 谌微微, 杨风丽, 庄圆, 徐铭辰, 胡虞杨. 利用古地磁学方法恢复钻孔岩心原始方位可靠性的探讨:以塔里木盆地钻井为例[J]. 地质科技通报, 2023, 42(6): 266-280. doi: 10.19509/j.cnki.dzkq.tb20220255
Chen Weiwei, Yang Fengli, Zhuang Yuan, Xu Mingchen, Hu Yuyang. On the reliability of drilling core reorientations using palaeomagnetic methods: A case study from the boreholes in the Tarim Basin[J]. Bulletin of Geological Science and Technology, 2023, 42(6): 266-280. doi: 10.19509/j.cnki.dzkq.tb20220255
Citation: Chen Weiwei, Yang Fengli, Zhuang Yuan, Xu Mingchen, Hu Yuyang. On the reliability of drilling core reorientations using palaeomagnetic methods: A case study from the boreholes in the Tarim Basin[J]. Bulletin of Geological Science and Technology, 2023, 42(6): 266-280. doi: 10.19509/j.cnki.dzkq.tb20220255

利用古地磁学方法恢复钻孔岩心原始方位可靠性的探讨:以塔里木盆地钻井为例

doi: 10.19509/j.cnki.dzkq.tb20220255
基金项目: 

同济大学实验教改项目 1350104103

国家自然科学基金重大研究计划重点项目"西太平洋地球系统多圈层相互作用" 92158207

详细信息
    作者简介:

    谌微微(1984—), 女, 工程师, 主要从事构造古地磁学、岩石磁学方面研究工作。E-mail: sww@tongji.edu.cn

    通讯作者:

    杨风丽(1964—), 女, 教授, 博士生导师, 主要从事构造、盆地分析与油气评价方面研究工作。E-mail: Yangfl@tongji.edu.cn

  • 中图分类号: P318.44;P634

On the reliability of drilling core reorientations using palaeomagnetic methods: A case study from the boreholes in the Tarim Basin

  • 摘要:

    针对非定向钻孔岩心原始方位难以确定的科学问题, 利用塔里木盆地5口钻井(TKQ101井、SHUN9井、TAT19井、TZ18井和TS108井)志留纪无定向砂岩样品, 对典型样品进行了岩石磁学、扫描电镜(SEM)和能谱分析(EDS)等实验, 明确了样品的主要载磁矿物, 之后对43块样品进行了退磁处理, 并分析了校正后的磁化率各向异性(AMS)最大轴(Kmax轴)指示的古水流方向, 探讨了利用剩磁恢复岩心原始方位的可靠性。AMS结果揭示的沉积组构支持整个钻孔回次地层近似水平; 岩石磁学、SEM和EDS实验结果表明TKQ101井样品主要载磁矿物为磁铁矿、含有少量针铁矿和赤铁矿, 其他钻井样品主要载磁矿物为磁黄铁矿和磁铁矿。43块样品的系统退磁实验结果显示, TKQ101井岩心样品可分离出可靠的现代场黏滞剩磁方向(VRM)和志留纪地层原生剩磁方向(ChRM), 经VRM和ChRM各自计算获得岩心原始方位旋转量(R, R', 其中R, R'分别为利用VRM和ChRM磁偏角获得的岩心原始方位旋转量)一致, 校正后的Kmax指示的古水流方向也与地质证据相吻合, 支持TKQ101井岩心原始标志线方位需逆时针旋转258.0°~262.0°;其他4口钻井岩心退磁结果呈现单分量特征, 综合分析明确其经历了由喜山期油气运移、聚集等流体活动导致的化学重磁化, 携带的剩磁为现代地磁场的黏滞剩磁和喜山期重磁化成分叠加结果。通过校正后Kmax轴指示的古水流方向和地质证据验证后, 揭示利用VRM获得的恢复岩心原始方位旋转量R较为可靠。综上, 钻井岩心原始方位恢复需要旋转的角度如下: TKQ101井岩心在逆时针旋转258.0°~262.0°后即可获得可靠的原始标志线方位; SHUN9井第4, 5, 6回次岩心标志线的方位需分别逆时针旋转148.1°, 221.2°和318.2°;TAT19钻井第3, 5回次岩心标志线的方位需分别逆时针旋转269.8°, 155.9°;TS108井和TZ18井岩心标志线的方位需分别逆时针旋转239.3°, 256.6°。

     

  • 图 1  塔里木盆地构造简图[34-37] (红色实心圆为钻井取样位置)

    Figure 1.  Simplified tectonic map of the Tarim Basin

    图 2  岩心取样方法及坐标轴转换示意图(x′, y′, z′为钻井岩心的三轴方向;x, y, z为古地磁样品的三轴方向)

    Figure 2.  Sampling methods and schematic diagram of coordinate axis conversion for drill cores

    图 3  柯坪塔格组砂岩样品的磁化率各向异性椭球主轴的等面积投影图(a)及相关参数分析图(b, c)

    Figure 3.  Stereoplots of three principal axes of the AMS ellipsoid and plots of AMS parameters for the Kepingtag Formation sandstone

    图 4  柯坪塔格组砂岩典型样品的岩石磁学结果

    a~c.磁化率随温度变化曲线(χ-T),红色和蓝色曲线分别代表加热和冷却曲线;d~f.等温剩磁(IRM)获得曲线和饱和等温剩磁的反向场退磁曲线;g~i.三轴饱和等温剩磁系统热退磁曲线

    Figure 4.  Rock magnetic results of representative sandstone samples of the Kepingtag Formation

    图 5  柯坪塔格组砂岩典型样品扫描电镜(a~c)与能谱分析图(d~f)

    Figure 5.  Scanning electron microscope images and energy dispersive spectral of representative sandstone samples from the Kepingtag Formation

    图 6  典型样品的热退磁和交变退磁正交矢量图

    实心点代表水平面投影,空心点代表垂直面投影;蓝色点代表参与低温分量统计的步骤,红色点代表参与高温分量统计的步骤;NRM代表天然剩余磁化强度;T代表温度(℃)

    Figure 6.  Zij derveld diagrams of the thermal and alternating-field demagnetization results of representative samples

    图 7  磁组构Kmax轴根据VRM获得的原始方位旋转量(R)校正后的等面积分布图(a~c)和玫瑰花图(d~f)

    b~c中红色实心圆分别代表TS108、TZ18井Kmax校正后在等面积投影图上的分布

    Figure 7.  Equal-area projections(a~c) and rose diagrams(d~f) of the corrected Kmax axis by the original azimuthal rotation(R) obtained from VRM

    表  1  下志留统柯坪塔格组(S1k)钻井岩心编号、深度和岩性

    Table  1.   The number ID, depth and lithology of drilling cores from the Lower Silurian Kepingtag Formation

    样品号 回次 深度/m 岩性 块号
    TKQ 101井S1k TKQ101-1 2 696.5 紫灰色粗粒石英砂岩,绿灰、紫灰色中粒石英砂岩,紫灰色细粒石英砂岩,局部见紫色泥质团块 18
    TKQ101-2 2 697.6 20
    TKQ101-3 2 698.8 26
    TKQ101-4 2 699.7 33
    TKQ101-5 2 700.5 35
    SHUN9井S1k SHUN9-1 5 433.0 灰色中粒岩屑石英砂岩 5
    SHUN9-2 5 434.7 12
    SHUN9-3 5 435.7 16
    SHUN9-4 5 437.6 29
    SHUN9-5 4共39 5 439.4 37
    SHUN9-6 5 470.1 灰色油迹含沥青质中粒岩屑石英砂岩 5
    SHUN9-7 5 470.6 7
    SHUN9-8 5 471.9 14
    SHUN9-9 5 473.5 22
    SHUN9-10 5共44 5 476.0 35
    SHUN9-11 5 579.4 浅灰色油斑细粒岩屑石英砂岩 8
    SHUN9-12 5 580.3 15
    SHUN9-13 5 582.4 26
    SHUN9-14 5 583.7 31
    SHUN9-15 6共38 5 584.7 34
    TAT19井S1k TAT19-5 5 317.5 砂岩 6
    TAT19-6 5 318.0 绿灰、灰色油迹-油斑细粒岩屑石英砂岩、油斑含砾细粒岩屑石英砂岩,细粒岩屑石英砂岩 12
    TAT19-7 5 319.7 38
    TAT19-8 5 321.0 58
    TAT19-9 3共67 5 321.9 65
    TAT19-10 5 380.6 砂岩 2
    TAT19-11 5 381.5 绿灰、浅灰色中粒、细粒岩屑石英砂岩 7
    TAT19-12 5 382.4 12
    TAT19-13 5 383.0 17
    TAT19-14 5 383.9 23
    TAT19-15 5共31 5 384.6 31
    TS108井S1k TS108-7 5 473.0 粉砂岩 7
    TS108-8 5 474.4 12
    TS108-9 5 475.8 19
    TS108-10 5 476.5 26
    TZ18井S1k TZ18-9 5 048.2 长石石英砂岩 14
    TZ18-10 5 049.8 灰色粉砂、细砂岩,与绿灰色泥岩互层 23
    TZ18-11 5 050.4 凝灰岩 27
    TZ18-12 5 051.6 39
    TZ18-13 5 052.7 49
    下载: 导出CSV

    表  2  塔里木志留纪柯坪塔格组(S1k)岩心的黏滞剩磁方向数据

    Table  2.   Summary of the VRM directions for the Silurian Kepingtag Formation(S1k) cores in Tarim

    钻井编号 n 载磁矿物岩心回次 黏滞剩磁(VRM)分量/(°) 采样点的现代场方向/(°)
    DVRM IVRM IYXC к α95 DM IM R
    TKQ101井 4 磁铁矿、赤铁矿、针铁矿 240.7 63.6 59.7 18.2 22.1 0.4 59.5 240.3
    1-3拟合* 3 258.7 64.8 60.0 38.6 20.1 0.4 59.5 258.3
    SHUN9井 18 磁黄铁矿、磁铁矿
    1-5拟合 8* 回次4 149.0 66.6 63.6 16.6 14.0 0.9 58.2 148.1
    6-10拟合 5 回次5 222.1 73.8 70.8 39.4 12.3 0.9 58.2 221.2
    11-15拟合 5 回次6 319.1 81.2 72.0 48.6 11.1 0.9 58.2 318.2
    TAT19井 10 磁黄铁矿、磁铁矿
    5-9拟合 4 回次3 271.1 77.2 75.3 49.1 13.2 1.3 60.8 269.8
    10-15拟合 6 回次5 157.2 83.5 77.0 73.3 7.9 1.3 60.8 155.9
    TS108井 6 磁黄铁矿、磁铁矿 240.4 86.3 78.1 38.7 10.9 1.1 59.8 239.3
    TZ18井 5 磁黄铁矿、磁铁矿 257.8 83.4 81.4 103.3 7.6 1.2 57.6 256.6
    注:n.参与古地磁统计的样品数;1-3拟合*.TKQ101井删除样品4A后的拟合结果;8*.SHUN9井回次4中含3块平行样品参与统计;DVRMIVRM分别为实测获得的黏滞剩磁磁偏角,磁倾角;IYXC.依据YXC磁倾角算法获得的磁倾角;к.统计精度参数;α95.95%置信圆锥半顶角;DMIM分别为钻井采样点的现代场磁偏角和磁倾角;R=DVRM-DM
    下载: 导出CSV
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