西准噶尔克拉玛依后山地区不同方向劈理特征及其动力学背景

李理; 王国灿; 晏文博; 彭超; 张云; 赵红伟

doi:10.3799/dqkx.2015.041

西准噶尔克拉玛依后山地区不同方向劈理特征及其动力学背景

doi: 10.3799/dqkx.2015.041

李理^{1, 2, 3,},
王国灿^{1, 2, ,},
晏文博²,
彭超²,
张云²,
赵红伟²

1.
中国地质大学地质调查研究院, 湖北武汉 430074
2.
中国地质大学地球科学学院, 湖北武汉 430074
3.
长江勘测规划设计研究院岩土总公司, 湖北武汉 430074

基金项目:

中国地质调查局项目"西准噶尔克拉玛依后山地区深部地质调查试点" 1212011220245

新疆1∶25万铁厂沟镇幅(L45C002001)与克拉玛依市幅(L45C003001)区调修测项目 1212011120502

详细信息

作者简介:
李理(1989-), 男, 硕士研究生, 主要从事构造地质学研究.E-mail: lilicug@163.com

通讯作者:
王国灿, E-mail: wgcan@cug.edu.cn

中图分类号: P54
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出版历程
- 收稿日期: 2014-06-09
- 刊出日期: 2015-03-15

Characteristics of Cleavages with Different Directions in Houshan Area of Karamay, Xinjiang, NW China and Their Geodynamic Background

Li Li^{1, 2, 3
,},
Wang Guocan^{1, 2
, ,},
Yan Wenbo²,
Peng Chao²,
Zhang Yun²,
Zhao Hongwei²

1.
Institute of Geological Survey, China University of Geosciences, Wuhan 430074, China
2.
School of Earth Sciences, China University of Geosciences, Wuhan 430074, China
3.
Geotechnical Corporation, Yangtze River Survey Planning and Design Institute, Wuhan 430074, China

摘要

摘要: 劈理构造是一定应力场中形成的具有透入性的面状构造, 一般代表变形过程中的最大压扁面.通过了解某一区域的劈理特征和发育序次, 能对该区域的构造变形序次和大地构造演化研究有一定的指示意义.在准噶尔盆地西北缘扎伊尔山石炭纪地层中发育多组透入性的劈理构造, 通过实地对研究区内劈理系统性地观察, 理出了3类劈理: (1)早期与蛇绿混杂岩构造就位相关的劈理; (2)晚期顺达尔布特断裂和哈图断裂发育的断裂劈理以及(3)方位十分稳定, 与层理发生不同程度置换, 构成不同大小的夹角, 代表近南北向区域性挤压运动的近EW向劈理.早期劈理产生于晚石炭世早晚之交, 与研究区内蛇绿混杂岩系在晚石炭世陆块斜向汇拢洋盆汇聚闭合、蛇绿混杂岩陆续构造就位于上覆相对较新的地层系统有关; 大型断裂劈理与区域内二叠-三叠纪大规模的北东-南西向断裂左旋走滑有关; 东西向劈理切过305±15 Ma的花岗斑岩脉, 而未影响到不整合于石炭系地层之上的中生代地层(最老为晚三叠世), 结合区域构造背景确定其形成时限为二叠纪末-早中三叠世, 与第2类劈理近于准同时, 可能与西伯利亚板块向南推挤导致的近南北向陆内挤压有关.
- 劈理 /
- 石炭纪 /
- 层劈置换 /
- 构造变形 /
- 西准噶尔
Abstract: Cleavage is a type of penetrative planar rock feature produced under certain stress fields, commonly normal to the direction of maximum compression. Detailed investigation into the physical characteristics and sequences of different cleavages can facilitate the understanding of the regional deformational history, and further the tectonic evolution of a given area. Three categories of cleavages have been recognized through systematic observations of the penetrative cleavages developed in the Carboniferous turbidites in the Zaire Mountains of western Junggar: (1) relatively earlier cleavages associated with the tectonic emplacement of ophiolites; (2) later fault-related cleavages developed along major faults, such as the Darbut and Hatu faults; (3) cleavages with rather consistent east-west strike across region, and at various angles to bedding planes, which denote a widespread north-south regional compression. The earlier cleavages were formed during the Early-Late Late Carboniferous, when the older (Ordovician to Devonian) ophiolites got emplaced into the overlying younger (Carboniferous) strata due to the oblique convergence of different blocks and closing of ocean basins. The fault-related cleavages were related to extensive sinistral strike slip along NE-SW trending faults during the Permian-Triassic. The east-west cleavages didn t affect Mesozoic strata (the oldest of Late Triassic) in the region and crosscut granite porphyry veins dated as 305±15 Ma. In the consideration of the extensional tectonic background of the area from the Late Carboniferous to Perimain, the east-west cleavages probably lasted from the latest Permian to Middle Triassic, roughly concurrent with the fault-related cleavages of the second type, both of which signify an intracontinental north-south compression concurred with the southward movement of the Siberian plate.
- cleavage /
- Carboniferous /
- bedding-cleavage intersection /
- tectonic deformation /
- western Junggar

HTML全文

图 1 研究区位置及不同劈理带分布

a.新疆北部构造格架简图据Xiao et al.(2008)修改；b.克拉玛依后山地区地质简图和3类不同方向劈理的空间分布.1.第四系；2.新近系独山子组；3.下白垩统吐谷鲁群；4.上侏罗统齐古组；5.中侏罗统头屯河组；6.中侏罗统西山窑组；7.下侏罗统三工河组；8.下侏罗统八道湾组；9.上三叠统小泉沟组；10.中-上二叠统库吉尔台组；11.上石炭统-下二叠统库吉尔台组；12.下-上石炭统哈拉阿拉特组；13.下石炭统太勒古拉组；14.下石炭统包古图组；15.下石炭统希贝库拉斯组；16.中奥陶统科克沙依组；17.正长花岗岩；18.花岗闪长岩；19.二长花岗岩；20.达尔布特中志留世-中泥盆世蛇绿混杂岩；21.克拉玛依-白口泉中奥陶世-晚志留世蛇绿混杂岩；22.玛里雅晚寒武世蛇绿混杂岩；23.整合地层界线；24.不整合地层界线；25.实测断层；26.地层产状(°)；27.走廊带区域范围；28.大型断裂带劈理；29.蛇绿混杂岩构造就位相关劈理化带；30.区域性90°方向强劈理带；31.达尔布特蛇绿混杂岩带两侧劈理统计的空间范围

Fig. 1. Location of the study area and distribution of different cleavages in the Houshan area of Karamay, Xinjiang, NW China

下载: 全尺寸图片幻灯片

图 2 达尔布特蛇绿混杂岩内部的劈理变形特征

a.沿劈理面分布有较多的石英质脉体，与定向排列的暗色岩石一起构成明暗相间的条带状构造岩块；b.混杂岩中的强劈理化；c.玄武岩中的强劈理化；d.达尔布特混杂岩带内部碎屑岩岩片中的密集劈理；e.达尔布特混杂岩带内部强劈理化含砾砂岩中的扁豆状砾石，砾石长轴平行劈理面上拉伸线理方向；f.混杂岩内部密集劈理S形弯曲指示左旋走滑

Fig. 2. Deformational characteristics of the cleavages distributed in the Darbut ophiolitic mélange, Xinjiang, NW China

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图 3 达尔布特混杂岩两侧及内部劈理密度统计，同一岩性在不同空间分布的劈理差异

a. 野外实地进行劈理密度统计照片；b.达尔布特蛇绿混杂岩带与围岩界线处深灰色凝灰质粉砂岩劈理密度80片/10 cm；c.离达尔布特蛇绿混杂岩北界约1 km处的深灰色凝灰质粉砂岩劈理密度56片/10 cm；d.离达尔布特蛇绿混杂岩北界约2 km处烟灰色凝灰质细粉砂岩劈理密度40片/10 cm；e.离达尔布特蛇绿混杂岩北界约3 km处的凝灰质粉砂岩劈理密度15片/10 cm

Fig. 3. Field measurement of the cleavage densities, showing different cleavage styles of the same lithology in and away from the Darbut ophiolitic mélange, Xinjiang, NW China

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图 4 达尔布特混杂岩两侧及内部劈理、层理产状和劈理密度特征

a.达尔布特混杂岩附近局部地质简图(红色字体表示空间所测得的劈理密度，表示方法为劈理产状-岩性-每10 cm的劈理条数)；b.达尔布特蛇绿混杂岩带两侧及内部劈理和层理的等密图，红点表示产状面的法线投影；c.根据图a中数据所作出的距达尔布特蛇绿混杂岩北界不同距离的不同岩性中劈理密度变化趋势，以达尔布特蛇绿混杂岩北西界为原点，达尔布特蛇绿混杂岩北西方向距离为负，南东方向距离为正.cg.中粗粒杂砂岩；ms.泥质粉砂岩；ss.凝灰质粉砂岩

Fig. 4. Characteristics of the attitudes of the bedding and cleavage and cleavage densities in the vicinity of the Darbut ophiolitic mélange, Xinjiang, NW China

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图 5 达尔布特断裂与哈图断裂的劈理特征

a.达尔布特断裂的宏观照片，发育一系列的断层三角面和断层崖，断层面陡峭；b.与达尔布特断裂带平行的系列断层面内破碎的硅质岩不对称透镜体，指示达尔布特断裂平面上的左旋走滑；c.达尔布特断裂产生系列的与断裂相关的劈理，其S形弯曲指示左旋走滑；d.哈图断裂的宏观照片，山前断层的第四纪活动形成陡坎；e.哈图断裂破碎带内不对称构造透镜体指示平面上的左旋平移；f.顺哈图断裂产出的石英脉与劈理呈小角度斜交，锐角的方向指示平面上的左旋走滑

Fig. 5. Characteristics of the cleavages in and near the Darbut and Hatu fault belts, Xinjiang, NW China

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图 6 克拉玛依后山地区东西向劈理的野外特征

a~d.东西向劈理与层理的不同角度交切关系；a.层理与劈理近平行；b.层理与劈理小角度相交；c.层理与劈理大角度相交；d.层理与劈理垂直；e.富硅质与富泥质层互层岩层表现出明显的劈理折射现象，呈弧形弯曲；f.近东西向劈理对层理的置换, 局部层理透镜体与劈理平行

Fig. 6. Field photographs of the EW direction cleavages in the Houshan area of Karamay, Xinjiang, NW China

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图 7 柳树沟-太勒古拉走廊带地质简图和层理、劈理、断层的等密图

Fig. 7. Contour diagram of the bedding, fault and cleavage in the Liushugou-Tailegula corridor belt

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图 8 宝贝-达尔布特走廊带地质简图和层理、劈理的等密图

Fig. 8. Contour diagram of the bedding, fault and cleavage in the Baobei-Shimiankuang corridor belt

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图 9 石棉矿地区小尺度追索路线层劈关系解剖

a.凝灰质粉砂岩与中粗砂岩中显示小角度相交的层劈关系；b.中粗砂岩与粉砂岩界线处层理与劈理大角度相交，中粗砂岩中劈理稀疏，冲刷构造显示中粗砂岩地层较新；c.泥质含量高的粉砂岩中密集性的EW向劈理与层理相垂直；d.层理和灰岩透镜体受EW向劈理置换发生S型或蛇形弯曲褶皱，枢纽陡倾伏；e.EW向劈理对层理的置换和改造，岩性界面呈现嵌入状；f.凝灰质粉砂岩中层理与劈理近于垂直，劈理密集

Fig. 9. Analysis of bedding-cleavage relationships by small-scale route tracing in the Shimiankuang area, Xinjiang, NW China

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图 10 EW向劈理在不同岩性中的显微特征和成因机制

a.在平行劈理面的切片中，受劈理影响的含砾粗砂岩的显微构造，微劈石主要由岩屑和长石组成，劈理域由泥质或细小矿物颗粒组成，形成黑白相间的系列条纹；b.含砾粗砂岩中石英长石颗粒发育长轴平行劈理迹线的形态优选组构；c.在平行劈理面的切片中，中粗粒岩屑砂岩在显微镜下照片，沿裂隙矿物颗粒呈现一定的排列方式，垂直最大压缩方向的颗粒边界上被溶解出的物质向低应力区迁移和堆积，压溶作用明显；d.斜长石颗粒受强压溶作用发生破裂，应力分解沿破裂面发生轻微的机械旋转形成劈理域；e.斜长石单颗粒发生旋转的正交镜下显微照片，与图d相对应；f.凝灰质粉砂岩的显微组构，难溶残余矿物与不透明矿物表现出了较好的定向排列特征

Fig. 10. Microscopic deformational features of different lithologies influenced by the EW direction cleavages in the Houshan area of Karamay, Xinjiang, NW China

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图 11 克拉玛依后山地区受EW向劈理改造的花岗斑岩脉U-Pb年龄数据结果

a.走向20°E岩脉在空间上宏观延伸；b.岩脉后期叠加90°E方向的劈理；c.岩脉在显微镜4倍单偏光下所显示的显微结构；d.样品N1112-1锆石同位素比率谐和图和U-Pb年龄分布；e.锆石颗粒阴极发光图像，颗粒大小与数量，每个分析点的²⁰⁶Pb/²³⁸U年龄

Fig. 11. U-Pb dating of a granite porphyry vein crosscut by the EW direction cleavages in the Houshan area of Karamay, Xinjiang, NW China

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图 12 准噶尔西北缘石炭-三叠纪构造转换期演化模型

a.晚石炭世早晚之交碰撞挤压使蛇绿混杂岩系以右旋走滑拉出，产生早期系列的与混杂岩构造就位相关的劈理；b.晚石炭世晚期-二叠纪后碰撞拉张环境发育系列的A型花岗岩、闪长岩及中基性岩墙；c.二叠纪-三叠纪之交，SN向陆内挤压产生断裂劈理与区域性的EW向劈理，对早期SN向、NE向构造强烈改造

Fig. 12. Evolution model of the Carboniferous-Permian tectonic transformation period in the northwest margin of the Junggar basin

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表 1 N1112花岗斑岩样品中锆石LA-ICP-MS锆石U-Pb同位素分析结果

Table 1. Results of LA-ICP-MS zirzon U-Pb isotopic analysis of the granite porphyry sample N1112

样品点号	²⁰⁷Pb/²⁰⁶Pb		²⁰⁷Pb/²³⁵U		²⁰⁶Pb/²³⁸U		²⁰⁸Pb/²³²Th		Total(Pb)(10^-6)	²³²Th(10^-6)	²³⁸U(10^-6)
样品点号	比值	1σ	比值	1σ	比值	1σ	比值	1σ	Total(Pb)(10^-6)	²³²Th(10^-6)	²³⁸U(10^-6)
1112-1-01	0.068 2	0.002 4	0.451 5	0.015 6	0.048 2	0.000 7	0.014 9	0.000 5	135.0	393.0	699.0
1112-1-02	0.082 5	0.003 3	0.555 0	0.025 9	0.047 7	0.000 7	0.023 9	0.001 3	198.0	376.0	1 067.0
1112-1-03	0.093 4	0.002 1	0.648 3	0.013 2	0.050 2	0.000 6	0.024 6	0.000 6	308.0	527.0	1 249.0
1112-1-04	0.105 1	0.005 8	0.683 9	0.034 9	0.048 3	0.000 9	0.028 1	0.001 7	39.6	65.2	187.0
1112-1-05	0.058 6	0.002 1	0.423 1	0.014 9	0.052 7	0.000 8	0.017 9	0.000 5	102.0	270.0	594.0
1112-1-06	0.034 4	0.001 5	0.225 4	0.009 1	0.044 0	0.000 8	0.010 2	0.000 6	120.0	254.0	744.0
1112-1-07	0.053 7	0.002 8	0.364 2	0.018 4	0.046 2	0.000 8	0.014 2	0.000 7	63.0	113.0	271.0

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