Late Paleozoic Fluid Systems and Their Ore-forming Effects in the Yuebei Basin, Northern Guangdong, China   总被引：1，自引：0，他引：1  

DENG Jun  YANG Liqiang  SUN Zhongshi  WANG Jianping  WANG Qingfei  CHENG Xueming  ZHOU Yinghua State Key Laboratory of Geological Processes  Mineral Resources  China University of Geosciences  Beijing  Key Laboratory of Lithosphere Tectonics  Lithoprobing Technology of the Ministry of Education  China University of Geosciences  Beijing School of Earth Sciences  Jilin University  Chuangchun  Jilin 《《地质学报》英文版》2005,79(5):673-687

Based on detailed and systematic researches of the geology of ore deposits, fluid inclusions and isotope geochemistry etc., and regarding the Late Paleozoic fluid system of the Yuebei Basin as an integrated object in this paper, we have revealed the temporo-spatial evolution law of the basin＇s fluid system and discussed its ore-forming effects by simulating and analyzing the distribution of ore-forming elements, the fluid thermodynamics and dynamics of evolution processes of this basin. The results show that Late Paleozoic ore-forming fluid systems of the Yuebei Basin include four basic types as follows. （1） The sea floor volcanic-exhalation system developed during the rapid basin slip-extension stage in the Mid-Late Devonian, which affected the Dabaoshan region. It thus formed the Dabaoshan-type Cu-Pb-Zn-Fe sea floor volcanic-exhalation sedimentary deposits. （2） The compaction fluid system developed during the stable spreading and thermal subsidence-compression stage of the basin in the Mid-Late Devonian. The range of its effects extended all over the whole basin. It resulted in filling-metasomatic deposits, such as the Hongyan-type pyrite deposits and pyrite sheet within the Fankou-type Cu-Pb-Zn-S deposits. （3） The hot water circulation system of sea floor developed during the stage of basin uplifting and micro-aulacogen from the late Late Carboniferous to Middle Carboniferous. The range of its effects covered the Fankou region. It thus formed MVT deposits, such as the main orebody of the Fankou-type Pb-Zn-S deposits. （4） The gravity fluid system developed during the stage of fold uplifting and the basin closed from Middle Triassic to Jurassic, forming groundwater hydrothermal deposits, e.g. the veinlet Pb-Zn-calcite orebodies of the Fankou-type Pb-Zn- S deposits. Migration and concentration of the ore-forming fluids were constrained by the state of temporo-spatial distribution of its fluid potential. Growth faults not only converged the fluids and drove them to move upwards, but also the fluids often crossed the faults to the edges of the basin at the bottom of these faults and the lithologic interfaces, and even migrated to the basin＇s edges from top to bottom along the faults, which may be one of the basic reasons for the stratabound deposits to cluster mainly along the contemporaneous faults on the inner border of the basin. The superposed mineralization resulting from the multi-stage activity of contemporaneous faults and ore-forming fluid systems in the basin may be one of the key factors for forming superlarge ore deposits.  相似文献   

A Review on the Global Stratotype Section and Point of the Permian-Triassic Boundary   总被引：6，自引：0，他引：6  

YIN Hongfu  TONG Jinnan  ZHANG Kexin Lab of Biological  Environmental Geology  China University of Geosciences  Wuhan  Hubei  State Key Lab of Geological Process  Mineral Resources  China University of Geosciences  Wuhan  Hubei 《《地质学报》英文版》2005,79(6):715-728

1 Introduction The Global Stratotype Section and Point (GSSP) of the Permian-Triassic Boundary (PTB) has been ratified by IUGS in 2001 (Yin et al., 2001). It is defined at the base of the Hindeodus parvus horizon, i.e. the base of Bed 27c of Meishan Section D, Changxing County, Zhejiang Province, South China. The PTB is important because it is not only an erathem boundary but also a great turning point of geological history symbolized by profound global changes and the strongest …  相似文献   

Comparison of the Typical Metallogenic Systems in the North Slope of the Tongbai-East Qinling Mountains and its Geologic Implications     

ZHANG Jing  CHEN Yanjing  QI Jinping  GE Jun State Key Laboratory of Geological Process  Mineral Resources  China University of Geosciences  Beijing  China Key Laboratory of Metallogenic Dynamics  Guangzhou Institute of Geochemistry  the Chinese Academy of Sciences  Guangzhou  China 《《地质学报》英文版》2009,83(2)

The Tongbai-East Qinling Mountains,an important part of the Central orogenic belt,is one of the most important metallogenic belts in China and contains lots of orogenic-type and VMS-type (Volcanogenic Massive Sulfide type)metallogenic systems.The Dahe and Shuidongling VMS-type Cu-Zn deposits,located in the Erlangping Group in Tongbai and East Qinling Mountains,respectively, show similar geological and geochemical features.The Huoshenmiao Formation in the East Qinling region and the Liushanyan Formation i...  相似文献   

Revision of the Clam Shrimp Genus Magumbonia from the Upper Jurassic of the Luanping Basin,Hebei,Northern China     

Peter BENGTSON  Helmut WILLEMS  Hiramichi HIRANO 《《地质学报》英文版》2009,83(1)

The diverse clam shrimp Nestoria-Keratestheria fauna is widely distributed in the Dabeigou Formation in northern Hebei and eastern Inner Mongolia of China.Its important component genus Magumbonia from the Dabeigou Formation in the Luanping Basin,northern Hebei,China,is revised on the basis of a scanning electron microscope (SEM) examination of the type species M.jingshangensis Wang,1984,which revealed morphological features not recognized previously.These include coarse reticulation on the umbo and promi...  相似文献   

基于频率搬移的地震资料约束测井资料外推   总被引：4，自引：0，他引：4       下载免费PDF全文

陆文凯  张善文 《地球物理学报》2004,47(2):354-358

于地震资料本身频带有限的特性,导致在利用地震资料作为约束条件进行测井资料外推时存在奇异性. 文中利用通信中常用的频率搬移技术,将频带有限的地震资料转化成一种频带拓宽的伪超分辨率资料来控制测井资料的外推,从而解决地震资料约束下的测井资料外推技术中的奇异性问题. 并利用同相轴自动追踪和时频分析技术,解决子波时变的问题,实现沿地层自适应地外推测井资料. 对实际资料的测井速度和反射系数外推结果表明, 此法具有较好的应用前景.  相似文献   

基于独立分量分析的多次波自适应相减技术   总被引：29，自引：7，他引：22       下载免费PDF全文

陆文凯  骆毅  赵波  钱忠平 《地球物理学报》2004,47(5):0-891

针对多次波自适应相减这个关键问题,文中首次提出利用独立分量分析技术来实现多次波和一次波的分离（简称ICAAMS）. 现有的多次波自适应相减技术大都是采用输出信号（一次波）能量最小准则,基于二阶统计量的技术. 本文提出的ICAAMS采用了输出信号非高斯性最大准则,并利用高阶统计量来表征非高斯性. 简单的褶积模型和复杂的有限差分模型资料处理结果表明, 本文提出的方法可以有效地分离一次波和多次波.  相似文献   

大气流场的拓扑结构   总被引：3，自引：1，他引：2       下载免费PDF全文

梁福明  时少英  刘式达  刘式适  付遵涛  辛国君 《地球物理学报》2004,47(4):584-589

用简化的大气运动方程,定性分析了大气中几种常见天气系统流场的拓扑结构. 研究表明,气旋反气旋流场与中心点附近的流形相对应;长波演化形成阻塞高压流场,与鞍点和中心点从合并到分离的流形相对应;台风和龙卷风的流场与三维空间中鞍-焦点附近的流形相对应. 研究大气流场的拓扑结构,可以直观清晰地揭示大气运动的形态和形成机理,有助于认识大气运动的规律. 文中讨论基于一定假设,结果与实际大气有差异,因而具有局限性.  相似文献   

2001年昆仑山口西MS8.1地震地表同震位移分布特征   总被引：10，自引：1，他引：9       下载免费PDF全文

陈杰  陈宇坤  丁国瑜  王赞军  田勤俭  尹功明  单新建  王志才 《地震地质》2004,26(3):378-392

沿长约 4 2 6km的 2 0 0 1年昆仑山口西MS8 1地震地表破裂带共获得 2 91个点的地表同震水平左旋位移数据 ,并在其中 1 1 1个点获得了垂直位移数据。该地震总体以左旋水平位移为主 ,兼具一定的垂直位移。最大地表左旋水平位移值可达 6 4m ,平均水平位移约为 2 7m ,绝大多数测点的垂直位移均 <1m。地表水平位移沿主破裂带走向位移梯度变化于 1 0 - 1～ 1 0 - 4之间 ,这一起伏变化可能起因于野外测量误差、沿主破裂带岩性或松散沉积物厚度的变化、地表破裂带几何结构的不均匀性、地表破裂走向的变化、不同破裂段在昆仑山口西 8 1级地震之前的地震中滑动量的起伏变化 ,以及大量非脆性变形、次级破裂的存在等。水平位移沿主破裂带的长波长 (数十公里至数百公里 )起伏变化较有规律 ,在布喀达坂峰以东表现为分别以 5个水平位移峰值为中心而有规律地起伏变化。这5个位移峰值分别对应于不同的次级地震地表破裂段。各破裂段水平位移峰值均向阶区或拐点逐渐衰减 ,不同地表破裂段位移峰值向两侧衰减的速率是不同的 ,这种位移梯度的不对称分布可能指示了地震破裂的扩展方向。上述位移分布特征真实地反映了地表可见脆  相似文献   

青藏高原及周边现今构造变形的运动学   总被引：31，自引：3，他引：28       下载免费PDF全文

张培震  沈正康  王敏  甘卫军 《地震地质》2004,26(3):367-377

青藏高原现今构造变形的定量化研究是理解其动力过程的基础 ,近年来高速发展的GPS(全球定位系统 )技术为测量大尺度现今构造变形提供了最有效的手段。我们利用青藏高原及周边的5 5 3个GPS观测数据给出了其现今构造变形的速度场 ,表明印度和欧亚板块之间的相对运动主要被青藏高原周边的地壳缩短和内部的走滑剪切所调整吸收。其中 ,喜马拉雅山系吸收了青藏高原总缩短量的 4 4%～ 5 3% ,北部的阿尔金山、祁连山和柴达木盆地吸收了 1 5 %～ 1 7% ,高原内部吸收了 32 %～4 1 %。青藏高原的“向东挤出”实际上是地壳物质的向东流动而不是刚性地块的挤出。这一地壳物质流动带在高原西部以地表张性正断层和共轭剪切走滑断层为特征 ,到高原中东部转换为巨型的弧形走滑断裂带 ,再到高原东北缘转换为地壳缩短和绕东喜马拉雅构造结的顺时针旋转。青藏高原的大尺度现今构造变形以连续变形为特  相似文献   

阿尔金北缘断裂雁丹图、长草沟河流阶地与构造抬升          下载免费PDF全文

郑荣章  徐锡伟  王峰  李建平  计凤桔 《地震地质》2004,26(2):189-199

宽谷及宽谷阶地的形成与流域内的构造抬升活动密切相关。文中在考察阿尔金北缘断裂东段雁丹图与长草沟宽谷的基础上 ,结合古气候资料 ,探讨了晚更新世晚期以来两地河流阶地所反映的构造抬升。雁丹图自约 16 1kaBP以来发育了 3级堆积阶地 (T1,T2 与T3) ,并出露埋藏主要宽谷。 3级阶地面年龄分别约为 16 1ka ,12 8ka ,6 2ka ,反映了 3次构造抬升的存在 ,代表了 3次构造抬升发生的时间。雁丹图自约 16 1kaBP以来的构造抬升速率约为 4 8～ 4 5mm/a ;12 8～ 6 2kaBP间的抬升速率约 6 4mm/a ;6 2kaBP以来为 3 1mm/a。长草沟在 7kaBP以来有 4级阶地发育 (T3,T2 ,T′1与T1) ,均为堆积阶地 ,并出露埋藏宽谷。其中T3与T2 出露埋藏主要宽谷 ,T′1与T1出露埋藏次要宽谷。T3,T2与T′13级阶地的阶地面年龄分别约为 7ka ,3ka,2 5ka。 4级阶地反映 2次构造抬升 ,一次在约 7kaBP ,一次在 3kaBP左右。自 7 0kaBP以来长草沟的抬升速率约为 5 9mm/a ,在 7～ 3  相似文献