河北大庙斜长岩杂岩体锆石U-Pb年龄及其地质意义   总被引：25，自引：21，他引：25  

赵太平陈福坤  翟明国夏斌 《岩石学报》2004,20(3):685-690

河北承德大庙斜长岩杂岩体是我国唯一的岩体型斜长岩。为了确定杂岩体的形成时代,作者从杂岩体主要组成岩石——苏长岩、纹长二长岩中选取锆石作U-Pb年龄测定,所获得的结晶年龄分别是1693±7 Ma、1715±6 Ma。这些锆石U-Pb年龄数据说明,大庙斜长岩杂岩体的侵位至少持续了约20 Ma。大庙斜长岩杂岩体和密云奥长环斑花岗岩、长城系大红峪组钾质火山岩,以及广泛发育的基性岩墙群一起可能代表华北陆块1750～1650 Ma大陆裂解事件的岩浆作用产物。  相似文献   

内蒙古赤峰地区安家营子金矿成矿流体研究   总被引：6，自引：1，他引：6  

李永刚翟明国  苗来成薛良伟  朱嘉伟关鸿 《岩石学报》2004,20(4):961-968

该金矿床产于晚燕山期安家营子二长花岗岩岩体内,受NNE向断裂带控制。矿化类型属蚀变岩型。矿物包裹体研冤表明,成矿流体为CO2-H2O-NaCl-KCl体系,来自安家营子花岗岩浆期后热液,其氢氧同位素组成分别为δD=-80.0~-96.5‰,δ18OH2O=4.5~5.7‰。主成矿期四个成矿阶段包裹体的均一温度和盐度分别为Ⅰ=340~360℃:Ⅱ=315~330℃,3.80~6.20 wt％／NaCl,CO2密度0.2~0.3 g／cm3;Ⅲ=245~285℃,3.5~4.5 wt％NaCl:Ⅳ=150~170℃,<2.0wt％NaCl。成矿流体盐度和CO2密度均较低。包裹体气相成分中(CH4 CO)／CO2<0.1,成矿环境为弱还原条件;液相成分中K Na 总量较高,K >Na 有利于碱质交代成矿作用。根据CO2包裹体获得资料计算,成矿压力为500~750×105Pa,成矿深度为2.0~2.5 km。流体控矿因素有水-岩反应、CO2与H2O-NaCl溶液不混溶和硫浓度降低等。其中以水-岩反应为主,它贯穿成矿全过程,控制原始成矿流体由碱性向弱碱性-弱酸性变化,使流体发生交代成矿作用。  相似文献   

晚太古代Sanukite（赞岐岩）与地球早期演化   总被引：9，自引：12，他引：9  

张旗王焰  钱青翟明国  金惟浚王元龙　简平 《岩石学报》2004,20(6):1355-1362

Shirey and Hanson(1984)将某些太古代的高镁闪长岩套称为sanukite(赞岐岩),类似于日本中新世(11～15Ma)Setouchi火山岩带的高镁安山岩。Sanukitoids由闪长岩-二长闪长岩-花岗闪长岩组成,不同于TTC岩套(奥长花岗岩-英云闪长岩-花岗闪长岩)。Sanukitoids具有下列地球化学特征:富Mg,Mg~#>0.60,Ni和Cr>100μg/g,Sr和Ba>500μg/g,LREE富集(大于球粒陨石100倍),无Eu异常。高镁安山岩在太古代很少见,而其相应的侵入岩高镁闪长岩或sanukitoids,虽然数量也很少,但却是各地晚太古代地体中随处可见的。Sanukitoids的原始岩浆是交代的地幔楔部分熔融形成的,随后可能经历了广泛的分离结晶作用。TTC和sanukitoids岩套可以相伴产出,二者均与板片熔融有关,TTG与其直接有关,sanukitoids可能与其间接有关。全球Sanukitoids主要集中在晚太古代时期,可能暗示板块的消减作用在～3.0Ga以后才起了重要的作用。  相似文献   

地球系统科学与成矿学研究   总被引：24，自引：6，他引：24  

翟裕生 《地学前缘》2004,11(1):1-10

在简述地球系统科学的基础上 ,文中提出了由地球系统科学引发的成矿学研究 3个观点 :(1 )成矿系统是一个特色的地质系统 ;(2 )成矿系统与其它系统的关联 ;(3)地质突发事件具有灾害和资源的两重性。针对地球系统科学要求和矿床学学科发展进程 ,提出了 5个亟待加强的研究领域或课题 :(1 )深部过程、浅表环境与成矿系统 ;(2 )重大事件与成矿 ;(3)生命活动与成矿 ;(4 )物理成矿作用和(5 )海洋成矿作用。在结语中 ,作者强调要从地球系统的大背景来研究成矿环境、成矿过程和成矿动力学 ,也即将传统的矿床成因研究提高到地球系统科学的层次 ,为矿床学的发展提供新的广阔的理论基础。  相似文献   

山西龙泉关韧性剪切带新认识   总被引：2，自引：0，他引：2  

孙占亮  李建荣  刘成如  张玉生  杨耀华  闫文胜 《华北地质》2004,27(2):92-100

龙泉关韧性剪切带位于山西、河北两省分水岭两侧的狭长地区内，全长约100km，宽2～14km，总体呈北北东向带状展布。据其变形特征在横、纵向上的明显变化，可分北、中、南三段：北段由眼球状片麻岩、长英质糜棱岩及构造透镜体组成，片麻岩中发育各类旋转碎斑构造，指示上盘(西盘)左旋剪切；中段由强直片麻岩组成，发育平直的片麻理及矿物拉伸线理，为S—L构造岩；南段由一系列线状强变形带及所挟持包绕的弱应变域所组成，变形岩石发育条带状、杆状构造。该剪切带内含有不同时期的变质岩系，主体为中太古代阜平期变质岩系，其构造形迹为一多期多相叠加的韧性剪切带；五台早期表现为伸展型近水平韧性剪切变形，是五台海盆早期扩张或裂解阶段的直观反映；吕梁期韧性剪切变形表现为逆冲推覆型。其形成及构造演化是区内早前寒武纪地质演化的缩影。  相似文献   

Hydrothermal Mineralization on the Mesoproterozoic Passive Continental Margins of China： A Case Study of the Langshan-Zha＇ertaishan Belt, Inner Mongolia, China     

PENGRunmin ZHAIYusheng 《《地质学报》英文版》2004,78(2):534-547

Most ore-forming characteristics of the Langshan-Zha‘ertaishan hydrothermal exhalation belt, which consists of the Dongshengmiao, Huogeqi, Tanyaokou and Jiashengpan large-superlarge Zn-Pb-Cu-Fe sulfide deposits, are most similar to those of Mesoproterozoic SEDEX-type provinces of the world. The characteristics include: (1) All deposits of this type in the belt occur in third-order fault-basins in the Langshan-Zha‘ertaishan aulacogen along the northern margin of the North China Platform; (2) these deposits with all their orebodies hosted in the Mesoproterozoic impure dolomite-marble and carbonaceous phyllite (or schists) have an apparent stratabound nature; ores display laminated and banded structures, showing clear depositional features; (3) there is some evidence of syn-sedimentary faulting, which to a certain extent accounts for the temporal and spatial distribution and the size of the orebodies in all deposits and the formation of intrabed conglomerates and breccias; (4) they show lateral and vertical zonation of sulfides; (5) The Cu/(Pb Zn Cu) ratio of the large and thick Pb Zn Cu orebodies gradually decreases from bottom to top; and (6) barite is interbedded with pyrites and sometimes with sphalerite. However, some characteristics such as the Co/Ni radio of the pyrites, the volcanism, for example, of the Langshan-Zha‘ertalshan metallogenic belt, are different from those of the typical SEDEX deposits of the world. The meta-basic volcanic rock in Huogeqi, the sodic bimodal volcanic rocks in the Dongshengmiao and potassic bimodal-volcanic rocks with blastoporphyfitic and blasto-glomeroporphyritic texture as well as blasto-amygdaloidal structure in the Tanyaokou deposits have been discovered in the only ore-bearing second formation of the Langshan Group in the past 10 years. The metallogeny of some deposits hosted in the Langshan Group is closely related to syn-sedimentary volcanism based on the following facts: most of the lead isotopes in sphalerite, galena, pyrite, pyrrhotite and chalcopyrite plot on both sides of the line for the mantle or between the lines for the mantle and lower crust in the lead isotope composition diagram; cobalt content of some pyrites samples is much higher than the nickel content (Co/Ni= 11.91-12.19). Some volcanic blocks and debris have been picked out from some pyritic and pyrrhotitic ores. All Zn-Pb-Cu-Fe sulfide orebodies in these deposits occur in the strata overlying metamorphic volcanic rocks in the only ore-bearing second formation. In the Jiashengpan deposit that lacks syn-sedimentary volcanic rocks in the host succession only Pb and Zn ores occur without Cu ore, but in the Dongshengmiao, Tanyaokou and Huogeqi deposits with syn-sedimentary volcanic rocks in the host succession Cu ores occur. This indicates a relatively higher ore-forming temperature. The process of synsedimentary volcanic eruption directly supplied some ore-forming elements, and resulted in secular geothermal anomaly favorable for the circulation of a submarine convective hydrothermal system, which accounts for the precipitation of deep mineralizing fluids exhaling into anoxidic basins along the syn-sedimentary fault system in the Langshan-Zha‘ertai rift. The Dongshengmiao, Tanyaokou, and Huogeqi deposits hosted in the Langshan Group appear to be a transitional type of mineral deposit between SEDEX and VMS-types but with a bias towards SEDEX, while the Jiashengpan deposit hosted in the Zha‘ertai Group is of a characteristic SEDEX type. This evidence, together with other new discoveries of Mesoproterozoic volcanic rocks and the features of lithogeny and metallogeny of the Bayun Obo deposit in the neighborhood emphasize the diversity, complexity and uniqueness of the Mesoproterozoic Langshan-Zha‘ertal-Bayun Obo ore belt.  相似文献   

基于面向对象的空间目标3维交互式建模的设计     

山海涛郭建星  翟辉琴张保明 《测绘学院学报》2004,21(3):205-207

3维数据模型的建立是实现真3维GIS的一个核心问题。在充分分析现有3维数据模型的基础上，比较了传统模型的优缺点。针对空间目标建模的特点，设计了一种面向对象的3维数据模型。考虑到软件的实用性和可扩展性，着重论述了3维交互式设计及数据管理。  相似文献   

刘公岛海洋牧场底层海水溶解氧浓度的变化特征     

李兆钦  李欣  孙利元  刘子洲  顾艳镇  翟方国  李培良 《海洋与湖沼》2019,50(1):86-99

由于缺乏长期观测资料,前人对山东半岛邻近海域海水溶解氧的时间变化和空间分布特征的研究较少。本文基于威海刘公岛海洋牧场于2016年7月20日至2017年3月14日期间,利用生态环境实时在线观测系统获得的底层海水的温度、盐度、水深、溶解氧数据,分析了该牧场海水溶解氧浓度的时间变化特征及其影响因素,并探讨了低氧灾害发生的可能性。结果表明在观测期间,该牧场海水溶解氧浓度以季节变化为主,冬季最大、夏季最小,其中2月份平均值最高,约为10.86mg/L,8月份平均值最低,约为5.91mg/L。同时海水溶解氧浓度也存在显著的小时变化和日变化,且变化幅度于8月份最大、3月份最小。影响海水溶解氧浓度变化的主要因素是海水温度,溶解氧浓度随着温度的季节性变化而变化。夏季,水体分层会使溶解氧浓度发生大幅度的降低,大风过程对于溶解氧浓度也有一定的影响,通过打破夏季的季节性温跃层使水体发生垂向混合从而为海底提供氧气,但大风过程之后的几天会出现溶解氧浓度降低的现象。本次研究发现刘公岛海洋牧场在观测期间不存在低氧现象。  相似文献   

Source tectonic dynamics features of Jiuzhaigou <Emphasis Type="Italic">M</Emphasis><Subscript>s</Subscript> 7.0 earthquake in Sichuan Province,China     

Shu-jian Yi  Chun-hao Wu  Yu-sheng Li  Chao Huang 《山地科学学报》2018,15(10):2266-2275

On August 8, 2017, a M_s 7.0 earthquake occurred 5 km to the west of Jiuzhaigou National Park, causing 25 deaths and injuring 525. The objective of this study was to explore the seismogenic fault of the earthquake and tectonic dynamics of the source rupture. Field investigations, radon activity tests, remote sensing interpretations, and geophysical data analyses were carried out immediately after the earthquake. The Jiuzhaigou earthquake occurred at the intersection of the northern margin of the Minshan uplift belt and the south part of the Wenxian–Maqin fault in the south margin of the West Qinling geosyncline. There are two surface rupture zones trending northwest (NW), which are ground coseismic ruptures caused by concealed earthquake faults. The rupture on the southwest is the structure triggering the earthquake, along the Jiuzhaitiantang–Epicenter–Wuhuahai. The other one on the northeast (Shangsizhai–Zhongcha–Bimang) is a reactivation and extension of the secondary fault trending NW. The source rupture of this earthquake is a strike-slip shear fracture associated with the fault plane trending NW 331° and steeply dipping 75°, which is continuously expanding at both ends. The tectonic dynamics process of the source rupture is that the “Jiuzhaigou protrusion” is left-lateral sheared along the seismogenic fault in the NW direction. Finally, the Maqin fault and the arc fault system at the top of the “Wenxian protrusion” will be gradually broken through sometime in far future, as well as earthquaketriggered landslides will be further occurred along the narrow corridor between the seismogenic faults. The research results revealed the basic geological data and tectonic dynamic mechanism in this earthquake.  相似文献   

Exploring seasonal acidification in the Yellow Sea   总被引：1，自引：0，他引：1  

Weidong ZHAI 《中国科学:地球科学(英文版)》2018,(6)

The Yellow Sea on the western continental margin of the North Pacific Ocean is of major ecological and economic importance. Four field surveys were conducted during May and November 2012, August 2015, and January 2016, investigating seasonal variations in dissolved oxygen and carbonate system parameters of this marginal sea. Results showed that the Yellow Sea cold water mass accumulated respiration-induced CO_2 in subsurface and bottom waters in summer and autumn, leading to acidified seawaters with critical carbonate saturation states of aragonite(Ω_(arag)) of less than 1.5. These seriously acidified seawaters occupied one third of surveyed areas in summer and autumn, likely affecting local calcified organisms and benthic communities. In a future scenario for the 2050 s, in which the atmospheric CO_2 mole fraction increases by 100 μmol mol-1, half of the Yellow Sea benthos would be seasonally covered by acidified seawater having a critical Ω_(arag) of less than 1.5. The corresponding bottom-water p H_T would be around 7.85 in summer, and 7.80 in autumn. Of the China seas, the Yellow Sea cold water mass represents one of the ecosystems most vulnerable to ocean acidification.  相似文献