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    湘西北奥陶系宝塔组灰岩龟裂纹构造特征、成因及其资源意义

    黄乐清 刘伟 柏道远 李泽泓 梁恩云 陈珍宝

    黄乐清, 刘伟, 柏道远, 李泽泓, 梁恩云, 陈珍宝, 2019. 湘西北奥陶系宝塔组灰岩龟裂纹构造特征、成因及其资源意义. 地球科学, 44(2): 399-414. doi: 10.3799/dqkx.2018.123
    引用本文: 黄乐清, 刘伟, 柏道远, 李泽泓, 梁恩云, 陈珍宝, 2019. 湘西北奥陶系宝塔组灰岩龟裂纹构造特征、成因及其资源意义. 地球科学, 44(2): 399-414. doi: 10.3799/dqkx.2018.123
    Huang Leqing, Liu Wei, Bai Daoyuan, Li Zehong, Liang Enyun, Chen Zhenbao, 2019. Characteristics, Petrogenesis and Resource Significance of the Limestone with Polygonal Reticulate Structure of Pagoda Formation, in Northwestern Hunan Province. Earth Science, 44(2): 399-414. doi: 10.3799/dqkx.2018.123
    Citation: Huang Leqing, Liu Wei, Bai Daoyuan, Li Zehong, Liang Enyun, Chen Zhenbao, 2019. Characteristics, Petrogenesis and Resource Significance of the Limestone with Polygonal Reticulate Structure of Pagoda Formation, in Northwestern Hunan Province. Earth Science, 44(2): 399-414. doi: 10.3799/dqkx.2018.123

    湘西北奥陶系宝塔组灰岩龟裂纹构造特征、成因及其资源意义

    doi: 10.3799/dqkx.2018.123
    基金项目: 

    中国地质调查局区域地质调查项目 1212011220510

    详细信息
      作者简介:

      黄乐清(1985-), 男, 工程师, 主要从事区域地质调查及沉积学的研究

      通讯作者:

      刘伟

    • 中图分类号: P583

    Characteristics, Petrogenesis and Resource Significance of the Limestone with Polygonal Reticulate Structure of Pagoda Formation, in Northwestern Hunan Province

    • 摘要: 湘西北上奥陶统宝塔组灰岩的龟裂纹构造在岩序上具有"下密上稀、过渡变形、不穿邻层、似泄水充填"的特点,是地史时期一种特殊的沉积构造.为了查明其成因机制及其与扬子海盆演化过程的内在联系,从湘西北龟裂纹灰岩的岩石学特征、裂缝特征、地球化学特征、盆地模型以及综合对比已知成因的"似龟裂纹构造"等诸多方面入手,经研究后认为龟裂纹构造属于一种受准同生期胶凝缩作用影响形成初始微缝,随后在构造挤压控制下、盆地快速下沉、盆内形成异常高压场的流体环境,驱使下伏富水岩层的灰泥物质向上挤入、充填、改造先期初始裂缝而形成.宝塔组龟裂纹构造的研究,为我们探究构造-流体-岩石多重作用机制提供了岩石学方面的资料;同时,该裂纹疏导功能良好,具有重要的成矿(油藏)意义.

       

    • 图  1  宝塔期扬子区古地理图及宝塔灰岩分布

      许效松(2001)有修改

      Fig.  1.  Paleogeograpic map and distribution of Baota Age from Late Ordovician, Yangtze Area

      图  2  湘西北地区中-上奥陶统地层综合柱状图

      Fig.  2.  Comprehensive column of Middle-lower Ordovician in Northwestern Hunan Province

      图  3  野外剖面及微观特征

      a.宝塔组灰岩宏观露头,瘤状构造与龟裂纹构造交互叠置;b.龟裂纹特征(具下宽上窄.切断缝合线的特点);c.龟裂纹中充填泥质,向上变少(垂直面);d.龟裂纹具似定向特征;e.充填泥质对两侧“围岩”浸染,其中见“围岩”碎斑;f.龟裂纹灰岩单层底部的泄水构造(灰绿色灰泥上侵至灰紫色龟裂纹灰岩中);g.含铁核形石,龟裂纹相对不发育;h.角石化石(未被龟裂纹切断);i.龟裂纹与瘤状构造呈过渡的现象;j.龟裂纹镜下特征,呈枝状;k.镜下,瘤状体与充填基质;l.镜下,龟裂纹充填基质中,三叶虫化石被错断产生位移,且长轴顺裂隙方向;m.镜下,不连续.孤立分布的裂纹;n.湘中地区(宁乡)棋梓桥组灰岩中的似龟裂纹构造;o.湘中地区(宁乡)棋梓桥组灰岩中的似龟裂纹构造中的充填物质特征(坐标X:19607780.05;Y:3118818.62)

      Fig.  3.  Outcrop and microscopic flakes characteristics

      图  4  湘西北地区奥陶系宝塔组及相邻地层碳酸盐岩微量元素多元素图解

      a.龟裂纹泥质充填物与牯牛潭组灰岩微量元素对比;b.龟裂纹泥质充填物与宝塔组灰岩微量元素对比

      Fig.  4.  Multi element diagram of the carbonate of upper Ordovician Baota Formation in the Northwestern Hunan Province

      图  5  宝塔组及邻层样品稀土元素配分模式

      Fig.  5.  Chondrite normalized REE diagram of the carbonate of Baota Formation

      图  6  湘西北龙山地区宝塔组龟裂纹形成机制

      Fig.  6.  The formation mechanism of cracked limestone in the Northwestern Hunan Province

      表  1  湘西北地区中-上奥陶统碳酸盐岩主量(%)、微量-稀土元素(10-6)地球化学分析数据

      Table  1.   The major elements (%)、Trace elements and REE contents (10-6) of the carbonate of Middle-upper Ordovician in the Northwestern Hunan Province

      样品号 dw-0 g-1 g-0 bt-4 bt-2 bt-3 bt-0 bt-1 对比数据
      岩性 瘤状泥灰岩 瘤状泥灰岩 泥灰岩 泥晶灰岩 泥晶灰岩 泥晶生屑灰岩 龟裂纹泥质 龟裂纹泥质 桐梓组砂屑灰岩 红花园组生物屑灰岩
      SiO2 6.42 45.39 56.16 5.05 7.79 9.54 46.85 45.39 4.04 5.16
      Al2O3 3.10 20.24 19.34 2.38 3.54 3.15 22.55 20.24 0.77 1.19
      MgO 0.88 2.35 2.54 0.90 0.81 0.96 1.88 2.35 2.12 1.74
      TiO2 0.134 1.960 0.830 0.149 0.212 0.210 2.030 1.960 0.025 0.041
      La 11.95 31.26 49.00 10.34 15.41 14.30 97.10 82.00 7.71 4.57
      Ce 24.46 61.01 110.00 24.12 33.95 32.90 181.00 218.00 15.49 8.73
      Pr 2.98 7.57 11.20 2.38 3.57 3.19 15.00 11.60 1.81 1.02
      Nd 11.85 28.41 40.80 9.32 13.75 12.60 42.00 31.60 7.08 3.90
      Sm 2.61 5.92 7.10 1.86 2.75 2.48 4.11 3.34 1.60 0.80
      Eu 0.47 1.25 1.58 0.33 1.19 0.60 1.34 1.32 0.19 0.02
      Gd 2.36 4.96 6.39 1.73 2.58 2.33 6.69 6.37 1.48 0.75
      Tb 0.40 0.86 0.90 0.29 0.47 0.47 0.74 0.66 0.28 0.13
      Dy 2.40 4.85 4.62 1.78 2.87 2.51 4.38 3.27 1.74 0.75
      Ho 0.53 1.06 0.89 0.40 0.60 0.52 0.98 0.76 0.39 0.17
      Er 1.52 2.92 2.48 1.09 1.65 1.57 3.49 2.64 1.13 0.50
      Tm 0.23 0.47 0.38 0.18 0.27 0.26 0.63 0.48 0.18 0.06
      Yb 1.43 2.88 2.34 0.95 1.71 1.51 4.45 3.22 1.16 0.37
      Lu 0.24 0.50 0.36 0.17 0.31 0.28 0.63 0.50 0.18 0.07
      Y 13.25 23.67 22.30 10.37 14.51 14.80 24.80 20.70 9.26 4.08
      ΣREE 63.43 153.92 238.04 54.94 81.08 75.52 362.54 365.76 40.42 21.84
      LREE 54.32 135.42 219.68 48.35 70.62 66.07 340.55 347.86 33.88 19.04
      HREE 9.11 18.50 18.36 6.59 10.46 9.45 21.99 17.90 6.54 2.80
      LREE/HREE 5.96 7.32 11.97 7.34 6.75 6.99 15.49 19.43 5.18 6.80
      Y/Ho 25.00 22.33 25.06 25.93 24.18 28.46 25.31 27.24 23.74 24.00
      LaN/YbN 5.65 7.33 14.15 7.35 6.09 6.40 14.75 17.21 4.77 8.86
      δEu 0.57 0.69 0.70 0.55 1.35 0.75 0.78 0.86 0.37 0.08
      δCe 0.94 0.91 1.07 1.11 1.04 1.10 1.01 1.48 0.98 0.95
      Cu 12.08 30.87 45.20 16.62 7.15 34.60 66.80 52.60 14.07 11.25
      Pb 11.42 19.40 47.20 15.63 16.56 18.50 49.10 45.80 15.16 6.69
      Zn 21.14 63.02 122.00 40.07 64.39 32.20 67.80 76.00 42.70 19.25
      Cd 0.26 0.54 0.13 0.27 0.75 0.16 0.15 0.15 0.46 0.30
      Rb 33.11 119.20 278.00 20.64 25.35 29.00 272.00 232.00 8.22 14.66
      W 0.42 1.00 13.80 0.85 2.42 2.68 13.10 11.80 1.00 0.17
      Mo 0.39 0.42 1.91 0.48 0.56 0.87 2.33 0.78 0.58 0.65
      As 2.34 2.10 14.70 3.96 53.43 67.50 23.70 37.20 3.31 3.19
      Bi 0.139 0.284 0.680 0.286 0.399 0.240 1.100 1.730 0.148 0.138
      Hg 0.068 0.238 0.022 0.343 0.389 0.022 0.029 0.025 0.239 0.089
      Sr 280.0 221.1 75.6 246.6 260.0 261.0 86.4 88.1 324.9 259.2
      Ba 408.2 1 047.0 1 060.0 290.8 2 596.0 316.0 1 920.0 1 880.0 158.4 75.7
      B 22 45 78 21 22 7 183 120 3 4
      Sn 2.0 1.2 77.0 1.4 2.0 5.6 9.7 14.0 1.3 1.8
      Ag 0.215 0.326 0.346 0.303 0.198 0.059 0.064 0.223 0.027 1.322
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