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1.
卡拉先格尔斑岩铜矿带位于我国新疆北部,大地构造位于中亚成矿域的中段、西伯利亚克拉通南缘与华北-塔里木克拉通北缘增生造山带的接合部位,夹于北西向额尔齐斯-玛因鄂博断裂带和北北西向可可托海-二台断裂带的交汇处。研究发现卡拉先格尔斑岩铜矿带在成矿构造地质、矿石组构、元素组合和成矿期次等方面表现出多期改造与叠加成矿的特征。在前期区域成矿背景、典型矿床研究的基础上,本文总结了卡拉先格尔斑岩铜矿带的构造演化与成矿过程:在中-晚泥盆世,卡拉先格尔斑岩铜矿带处于与俯冲有关的岛弧构造背景,有两期中酸性斑岩侵入与Cu-Au-Mo矿化作用;早石炭世时,区域处于碰撞造山阶段,NW向韧性剪切变形造成原斑岩中的矿化发生迁移与再定位,片理构造发育处局部得到富集;晚石炭世到二叠纪是后碰撞伸展阶段,形成了卡拉先格尔斑岩铜矿带一系列张性构造和叠加的脉状矿化;进入中生代后,常见热液脉状铜矿化充填叠加到早期矿化之上,但同时本矿带遭受强烈的抬升与剥蚀作用。 相似文献
2.
2008年5月12日14时28分,青藏高原东缘龙门山地区(四川汶川)发生了Ms8.0级地震。震后野外考察表明,5.12汶川地震发生在NE走向的龙门山断裂带上,该断裂带晚新生代以来的逆冲速率小于1mm/a,GPS观察结果表明其缩短速率小于3mm/a。这次5.12汶川地震造成了多条同震逆冲地表破裂带,总体长约275km,宽约15km,发震断裂机制主要为逆冲作用(由NW向SE逆冲)伴随右旋走滑。地表主破裂带沿龙门山断裂带的映秀—北川断裂发育,长约275km,笔者称为映秀—北川破裂带,破裂带具有逆冲兼右旋走滑性质。地表次级破裂带沿龙门山断裂带的前缘断裂安县—灌县断裂南段发育,长80km,笔者称为汉旺破裂带,破裂带基本为纯逆冲性质。在这两条破裂带之间发育两条更次一级的同震地表破裂带:一条长约20km呈NE走向的地表破裂带,笔者称为深溪沟破裂带,由于这条破裂带靠近主破裂带南段,并且与主破裂带变形特征一致,因此,笔者将深溪沟破裂带划归映秀—北川破裂带;另一条长约6km呈NW走向、由SW向NE逆冲并兼有左旋滑动的地表破裂带,笔者称为小鱼洞破裂带,它连接映秀—北川破裂带和汉旺破裂带,成为侧向断坡。另外,在灌县—安县断裂东侧的四川盆地内,由都江堰的聚源到江油发育一条NE向的沙土液化带,它可能是四川盆地西部深部盲断裂活动的结果。同震地表破裂带的分布特征表明,龙门山断裂带活动断裂具有强烈的逆冲作用并伴随较大的右旋走滑,断裂向四川盆地扩展。在龙门山断裂带上类似2008年5月12日Ms8.0汶川大地震的强震复发周期为3000~6000a。 相似文献
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塔里木盆地顺北地区发育大量走滑断裂带,并对油气的运聚成藏有重要控制作用。以顺北西部地区地震资料为基础,对顺北11号走滑断裂带的几何变形特征、活动性、活动期次及其形成机制等进行了分析。顺北11号走滑断裂带整体呈NNW走向延伸,具有垂向分层性和平面分段性。断裂带北段主体为压扭和张扭交互段,中段为两条次级断层控制的拉分地堑,南段由数条分支断层构成马尾状构造。顺北11号断裂带整体活动性由北向南减弱,运动学标志显示是一条右旋走滑断层。顺北11号断裂带主要经历了晚奥陶世和晚志留世-中泥盆世两期活动,部分地区的活动持续到石炭纪。顺北11号走滑断裂带的活动性和运动学特征与塔北地区NNW走向的走滑断裂体系比较相似,而不同于塔中地区的NE向左行走滑断裂体系。顺北11号走滑断裂带的形成主要受控于塔里木盆地北部天山洋多期俯冲挤压而产生的自北向南的挤压应力,断裂自北向南扩展延伸,类似于顺北5号走滑断裂带的北段。 相似文献
4.
近年来的国内外油气勘探实践表明含油气盆地内的基底走滑断裂带为一种新的高产油气富集带,油气勘探开发前景广阔。对基底走滑断裂的识别、几何学和运动学特征分析及“控储、控藏”作用方面的研究越来越引起高度关注。本文利用四川盆地东部涪陵地区的高精度三维地震剖面的断裂构造精细解析、相干体属性和水平时间切片分析、野外露头断裂特征观测等多种资料,基于走滑构造理论,在研究区新发现了规模较大的北西向和北东向基底走滑断裂带的分布,并建立了川东地区走滑断裂在剖面上直立断层和花状构造、平面上线性延伸和地质界线错开、空间上的“丝带效应”和“海豚效应”及主干断裂产状和力学性质“明显分段性”的识别标准。并提出了基于走滑断裂垂直位移量变化和两侧构造活动强度差异性对比分析厘定走滑方向的新方法;依据地震水平时间切片地层界线错开、走滑断裂两侧厚度差异估算走滑距离的方法,实际应用结果表明,NW向基底走滑断裂带现今整体呈现左行走滑特征,但不同时期走滑性质多变,自形成期以来至少经历了5次左行滑动与3次右行滑动,总体表现出“深部左行,浅部右行,北部活动强度大,南部活动强度小”的特点,左行走滑距累积可达到1 400~3 400 m。北东... 相似文献
5.
阿尔泰山活动断裂 总被引:13,自引:0,他引:13
文中介绍了位于亚洲腹地阿尔泰山地区的活动断裂。中国阿尔泰山 (阿尔泰山西南麓 )和蒙古阿尔泰山 (阿尔泰山的东麓 )以NNW向大型走滑断裂为主 ,科布多断裂是阿尔泰山东麓的一条主要NNW向走滑断裂 ,长度近 70 0km。第四纪中晚期右旋走滑速率可达 6 10mm/a ,其上发现有长逾2 0 0km的古地震形变带。富蕴断裂则是阿尔泰山西南麓的一条主要NNW向断裂 ,中晚第四纪的走滑运动速率为 (4± 2 )mm/a ,在中国阿尔泰山的西端还发育规模相对较小的NNW向右旋走滑断裂 ,中晚第四纪走滑速率为 (2± 1)mm/a。中国阿尔泰山 (阿尔泰山的西南麓 )还发育NWW向右旋走滑逆断裂 ,其规模相对较小 ,至中国阿尔泰山西端NWW向的额尔齐斯断裂具有明显的右旋走滑性质。蒙古阿尔泰山的南端则发育近东西向的左旋走滑逆断裂。在与戈壁阿尔泰山交汇部位 ,左旋走滑运动具主导作用。戈壁阿尔泰山发育的戈壁阿尔泰断裂带断续延伸可达 10 0 0km以上 ,目前的研究认为 ,其滑动速率为 12mm/a。其中的博格德断裂上 195 7年发生了戈壁阿尔泰 8.3级地震 ,形变带长约 2 5 0km。阿尔泰山活动断裂的规模、运动强度和强地震活动表明这里不仅受到遥远的印度板块北向推挤作用的影响 ,而且受到较近的地球动力学过程的影响或控制。 相似文献
6.
济阳坳陷东部长堤断裂是一条特征明显的走滑断裂带,以T2地震反射层(沙河街组二段底面反射层)为界,发育深层次和浅层次两套断裂系统。深层次断裂系统为长堤走滑断裂带的主体,发育R-P断层组合,剖面上呈丝带状构造样式,平面上呈发辫状构造样式;浅层次断裂系统由一组近南北向左阶羽状雁列带组成,雁列带中的每条断层为近南北向走滑断裂的T断层。Es3-Es2下期,长堤走滑断裂带开始活动,发育深层次断裂系统,系由济阳坳陷和渤中坳陷之间的构造调节作用所造成;Es上2-Ed期,发育浅层次断裂系统,与长堤深层次断裂持续活动以及沉积盖层的逐渐增厚有关,同时,郯庐断裂带开始对研究区的构造格局产生影响;Ng-Nm期,研究区处在巨大的北东向走滑递进应变带中,长堤近南北向走滑断裂带让位于郯庐断裂带控制的北东向走滑体系。 相似文献
7.
通过南海南部地球物理自由空间重力异常、化极磁力异常及二维地震资料的整理与解译,将南海南部的断裂体系划分为4种类型:分别为NW向走滑断裂、NE向拉张构造伴生断裂、SN向走滑断裂及南部弧形断裂。NW向走滑断裂主要对南海的板块划分具有指示作用; NE向的断裂多为拆离构造伴生的一些断裂,具有拉张板块边界的特点。NW走向的走滑断裂与新南海扩张有着密切的关系,而NE走向的断裂则控制着南海内部盆地的形成。SN走向的断裂在研究区内主要为越东—万安断裂带,由于其空间分布较长且构造作用明显切割深度较大,可以认为越东—万安断裂带是南海西侧的边界断裂带。笔者对马来西亚沙捞越地区的武吉米辛构造带野外露头的分析,可以进一步确定其为古南海俯冲之后抬升到地表之上较为有力的直接证据。 相似文献
8.
阿尔金断裂系西段——康西瓦断裂的 晚第四纪构造地貌特征研究* 总被引:17,自引:9,他引:17
阿尔金断裂带是青藏高原北部的一条大型左旋走滑断裂带,近EW向延伸2000多公里, 它构成了青藏高原与塔里木盆地之间的重要地质边界。康西瓦断裂位于阿尔金断裂带西段, 呈WNW-ESE向延伸约 700km。文章在高分辨率卫星遥感图像(印度遥感卫星5.8m分辨率)和数字高程地形模型(DEM)数据分析的基础上,并结合野外构造地貌考察观测,对康西瓦断裂的第四纪构造活动及其地貌特征进行了初步研究。沿断裂带发育的系统错断水系、错断冲积扇、挤压脊、走滑拉分盆地等典型构造地貌特征表明,该断裂晚第四纪经历了强烈的左旋走滑活动。同时,研究还揭示沿康西瓦断裂发育了一条长约80km的地表地震破裂带,最大同震左旋水平错位为4m,估算产生该地表破裂带的地震是一矩震级为Mw7.3的大地震。 另外,文章根据不同年代地表地貌特征的左旋错位距离,估算出康西瓦断裂晚第四纪以来的长期走滑速率为8~12mm/a,远低于早期估算的20~30mm/a,但是与阿尔金断裂带中、东段的地质估算结果9±2mm/a及GPS测量结果9±4mm/a接近。 相似文献
9.
四川汶川Ms 8.0级地震同震变形特征和分段性 总被引:6,自引:1,他引:5
汶川地震发育2条地表破裂带,一条沿中龙门山活动断裂带分布,另一条沿前龙门山活动断裂带分布,前者长超过200km,后者长约80km。同震变形在地表表现为逆冲膝折带,走向N45~60°E,形成公路路面隆起和农田陡坎。逆冲膝折带西北侧抬高,东南侧下降。在剖面上冲断带倾向北西,倾角50~60°。膝折带两侧相对高差沿映秀-北川断裂一般为2.5~3.0m,沿都江堰-汉旺断裂为1.5~1.1m。沿中龙门山活动断裂带,同震变形运动方式具有明显的分段性,映秀-擂鼓镇段,表现为逆冲,走滑现象不明显;北川-青川段既有逆冲又有右旋走滑分量。沿前龙门山活动断裂带,同震变形运动方式主要表现为逆冲,走滑位移和分段性不明显。 相似文献
10.
南海西缘断裂带是南海西部最主要的构造要素,从北到南贯穿了该区主要的沉积盆地,具有走滑断裂的性质。由于不同地质时期走滑方向的不同,形成了不同的断层组合,主要表现为负花状构造和北东向、北西向两组雁列断层以及平面上双马尾状构造组合。主体断裂带以单条式为主,区段式活动特征明显。在南北盆地之间的构造转换带表现为负花状构造-犁式断裂-多米诺式反向调节正断层的组合。综合分析认为,南海西缘断裂是一组长期活动的断裂带,大规模走滑活动从中始新世至第四纪时期,主要为右旋走滑,应力以张扭作用为主;但是在中中新世末期,走滑方向曾经发生转变,为左旋走滑,转为压扭应力,造成区域隆升,导致地层被剥蚀,南海西部盆地现今沉积-构造格局基本形成。 相似文献
11.
Tomomi Okada Akira Hasegawa Jun''ichi Suganomata Norihito Umino Haijiang Zhang Clifford H. Thurber 《Tectonophysics》2007,430(1-4):67-81
A shallow M6.4 inland earthquake occurred on 26 July 2003 in the northern part of Miyagi Prefecture, northeastern Japan. This earthquake was a typical inland thrust earthquake, a type that is common in NE Japan. We obtained a detailed seismic velocity structure in the focal area of this earthquake by the double-difference tomography method. Arrival-time data came from temporary seismic stations deployed above the mainshock fault plane. Both the P-wave and S-wave velocities in the hanging wall were lower than those in the footwall. Aftershocks were aligned along a zone where the seismic velocity changes rapidly. This is consistent with the interpretation that the 2003 northern Miyagi earthquake occurred along a fault that acted as a normal fault in the Miocene and has been reactivated as a reverse fault under the present compressional stress regime. The large slip area by the main shock rupture (asperity) corresponds to an area with relatively high P- and S-wave velocities. A zone with low Vp/Vs was detected along the aftershock area. One of the possible causes of this low-Vp/Vs zone is the existence of high-aspect-ratio pores that contain water. Hypocenters of the main shock, largest foreshock, and largest aftershock are also located within the low-Vp/Vs zone. 相似文献
12.
The integrated analysis of geological, seismological and field observations with lineament data derived from satellite images allows the identification of a possible seismogenic fault zone for an earthquake which occurred near Etne in southwestern Norway, on 29 February 1989. The hypocentre of the earthquake was located at the mid-crust at a depth of 13.8±0.9 km which is typical of small intraplate earthquakes. The Etne earthquake occurred as a result of normal faulting with a dextral strike-slip component on a NW–SE trending fault. Available geological and lineament data indicate correlation of the inferred seismogenic fault with the NW–SE trending Etne fault zone. An aeromagnetic anomaly related to the Etne fault zone forms a regional feature intersecting both Precambrian basement and allochthonous Caledonian rocks. Based on these associations the occurrence of the Etne event is ascribed to the reactivation of a zone of weakness along the Etne fault zone. Slope-instabilities developed in the superficial deposits during the Etne event demonstrate the existence of potentially hazardous secondary-effects of such earthquakes even in low seismicity areas such as southwestern Norway. 相似文献
13.
Field-based structural analysis of an exhumed, 10-km-long strike-slip fault zone elucidates processes of growth, linkage, and termination along moderately sized strike-slip fault zones in granitic rocks. The Gemini fault zone is a 9.3-km-long, left-lateral fault system that was active at depths of 8–11 km within the transpressive Late-Cretaceous Sierran magmatic arc. The fault zone cuts four granitic plutons and is composed of three steeply dipping northeast- and southwest-striking noncoplanar segments that nucleated and grew along preexisting cooling joints. The fault core is bounded by subparallel fault planes that separate highly fractured epidote-, chlorite-, and quartz-breccias from undeformed protolith. The slip profile along the Gemini fault zone shows that the fault zone consists of three 2–3-km-long segments separated by two ‘zones’ of local slip minima. Slip is highest (131 m) on the western third of the fault zone and tapers to zero at the eastern termination. Slip vectors plunge shallowly west-southwest and show significant variability along strike and across segment boundaries. Four types of microstructures reflect compositional changes in protolith along strike and show that deformation was concentrated on narrow slip surfaces at, or below, greenschist facies conditions. Taken together, we interpret the fault zone to be a segmented, linked fault zone in which geometrical complexities of the faults and compositional variations of protolith and fault rock resulted in nonuniform slip orientations, complex fault-segment interactions, and asymmetric slip-distance profiles. 相似文献
14.
浑河断裂带是深大断裂-郯庐断裂的北延分支,横贯抚顺市区,在断裂带之上及其两侧建有诸多大型工矿企业及民用建筑,断裂带的稳定与否关系到抚顺市的城市安全。近期,浑河断裂带抚顺市区段的个别次级断裂发生活动,并已造成严重的城市建筑破坏。局部断裂活动的成因,为城市决策者所关注。本文利用抚顺市城市平面控制网相隔17a的两期GPS测量数据,应用大地形变分析的理论方法,对浑河断裂带抚顺市区段的稳定性进行了定量分析,得出结论:浑河断裂带抚顺市区段的宏观地质构造在此期间活动性不明显。 相似文献
15.
Cretaceous deformation history of the middle Tan-Lu fault zone in Shandong Province, eastern China 总被引:13,自引:0,他引:13
Based on field analysis of fault-slip data from different rock units of the Cretaceous basins along the middle part of the Tan-Lu fault zone (Shandong Province, eastern China), we document polyphase tectonic stress fields and address the changes in sense of motion of the Tan-Lu fault zone during the Cretaceous. The Cretaceous deformation history of the Tan-Lu fault zone can be divided into four main stages. The first stage, during the earliest Cretaceous, was dominated by N-S extension responsible for the formation of the Jiaolai basin. We interpret this extension to be related to dextral strike-slip pull-apart opening guided by the Tan-Lu fault zone. The second stage, during the middle Early Cretaceous, was overwhelmingly rift-dominated and characterized by widespread silicic to intermediate volcanism, normal faulting and basin subsidence. It was at this stage that the Tan-Lu-parallel Yi-Shu Rift was initiated by E-W to WNW-ESE extension. The tectonic regime then changed during the late Early Cretaceous to NW-SE-oriented transpression, causing inversion of the Early Cretaceous rift basin and sinistral slip along the Tan-Lu fault zone. During the Late Cretaceous, dextral activation of the Tan-Lu fault zone resulted in pull-apart opening of the Zhucheng basin, which was subsequently deformed by NE-SW compression. This deformation chronology of the Tan-Lu fault zone and the associated Cretaceous basins allow us to constrain the regional kinematic models as related to subduction along the eastern margin of Asia, or related to collision in the Tibet region. 相似文献
16.
Surface Rupture of the 1515 Yongsheng Earthquake in Northwest Yunnan,and Its Seismogeological Implications 总被引:2,自引:0,他引:2
The 1515 M7? Yongsheng earthquake is the strongest earthquake historically in northwest Yunnan. However, its time, magnitude and the seismogenic fault have long been a topic of dispute. In order to accurately define those problems, a 1:50000 active tectonic mapping was carried out along the northern segment of the Chenghai–Binchuan fault zone. The result shows that there is an at least 25 km–long surface rupture and a series of seismic landslides distributed along the Jinguan fault and the Chenghai fault. Radiocarbon dating of the ~(14) C samples indicates that the surface rupture should be a part of the deformation zone caused by the Yongsheng earthquake in the year 1515. The distribution characteristics of this surface rupture indicate that the macroscopic epicenter of the 1515 Yongsheng earthquake may be located near Hongshiya, and the seismogenic fault of this earthquake is the Jinguan–Chenghai fault, the northern part of the Chenghai–Binchuan fault zone. Striations on the surface rupture show that the latest motion of the fault is normal faulting. The maximum co–seismic vertical displacement can be 3.8 m, according to the empirical formula for the fault displacement and moment magnitude relationship, the moment magnitude of the Yongsheng earthquake was Mw 7.3–7.4. Furthermore, combining published age data with the ~(14) C data in this paper reveals that at least four large earthquakes of similar size to the 1515 Yongsheng earthquake, have taken place across the northern segment of the Chenghai–Binchuan fault zone since 17190±50 yr. BP. The in–situ recurrence interval of Mw 7.3–7.4 characteristic earthquakes in Yongsheng along this fault zone is possibly on the order of 6 ka. 相似文献
17.
在区域地质构造研究中,龙门山断裂带也称为龙门山褶皱-冲断带或推覆构造带。许多研究者认为,2008年汶川8级地震的发震构造是这条断裂带或其中央映秀—北川断裂。笔者在深入分析龙门山断裂带的构造演化和岩石圈结构构造特征的基础上,着重探讨8级地震的发震构造,提出不同的认识。龙门山断裂带经历了松潘—甘孜造山带的前陆褶皱-冲断带(T3-J)、造山带(K-E)和青藏高原边缘隆起带(N-Q)3个动力学条件不同的演化阶段,在前两个阶段断裂带递进发展,第三阶段断裂带则被改造。从三维空间看,龙门山断裂带位于松潘—甘孜地块东南缘的上地壳内,并被推覆到扬子陆块上;而松潘—甘孜地块的中—下地壳和岩石圈地幔发生韧性增厚,而且向扬子陆块壳下俯冲,从而使浅、深部构造在垂向上形成"吞噬"扬子地块的"鳄鱼嘴"式结构。虽然在平面上汶川8级地震的主余震分布与映秀—北川断裂一致,但从剖面上看其震源所构成的震源破裂体位于龙门山断裂带之下的扬子陆块内。这种不一致性表明,8级地震的发震构造不是龙门山断裂带,而是扬子陆块内新生的高角度断裂,其走向基本与龙门山断裂带一致。推测这一震源断裂的形成过程是:当松潘—甘孜地块向东南推挤时,其前缘"鳄鱼嘴"构造咬合并错断被吞噬的扬子陆块部分,形成具有右旋逆平移性质的新断裂,导致汶川8级地震的发生。 相似文献
18.
R. Rexford Upp 《Engineering Geology》1989,27(1-4):375-412
The Maacama fault zone is a north-northwest trending, right-lateral zone of structural weakness in eastern Sonoma and Mendocino Counties, California, and fault-related landforms along its trace suggest that it may well have been active during Holocene time. Urbanization and dam construction in the vicinity of the zone have made it especially desirable to determine the extent and history of such geologically recent movements in order to better understand the seismic capability of faults within the zone.
The Maacama fault zone is a segment of one of two north-northwest trending zones of right-lateral faulting that diverge as major branches from the easterly side of the San Andreas fault zone north of Hollister. These branches extend at least as far north as Eureka and may mark the eastern boundaries of slivers of a separate tectonic plate.
This investigation was conducted to evaluate Holocene activity along the part of the Maacama fault zone in Mendocino County. The investigation shows that this zone comprises discontinuous, subparallel fault strands which extend from points south of the Sonoma—Mendocino county line to points north of Laytonville. Some fault segments are expressed by alignments of topographic features clearly caused by Holocene strike-slip movements. Other topographic features are less distinct and may well represent fault segments with pre-Holocene activity.
The Maacama fault zone creeps at a current rate of possibly as high as 2 mm/yr. The total amounts of Holocene offset are unknown.
Evidence obtained from exploratory trenches indicates that at least two surface rupture events have occurred within the past 16,200 years, that at least one has occurred within the past 8,310 years, and that there probably has been no surface rupturing within the past 1,140 years.
I conclude that surface offsets have occurred along major portions of the Maacama fault zone during Holocene time, and that this fault zone should be regarded as capable of producing a moderate to strong future earthquake with accompanying surface rupture in Mendocino County. 相似文献
19.
东准噶尔蒙西斑岩铜钼矿床脉体特征及其形成机制 总被引:5,自引:1,他引:4
蒙西斑岩铜钼矿床位于东准噶尔伊吾县琼河坝花岗岩北侧,以发育细脉、网脉状矿化为特征。脉体类型多样,包括石英脉、石英硫化物脉和硫化物脉等。根据脉体力学成因机制,其又可划分为水压破裂充填脉和构造破裂充填脉。构造破裂充填脉体按破裂形成的位错特征有正断与逆断两种。地表石英脉产状陡立,明显受断裂控制。脉体体积分数统计结果显示流体富集区呈向北缓倾的带状分布于深100~400m范围内,并与矿化富集带有较好的对应关系。脉体富集带内,脉体以共轭形式存在,一组为倾角较小的逆断破裂充填脉,另一组为倾角较大的正断破裂充填脉,他们可能为缓倾逆冲剪切带的次级破裂与充填脉,即富矿带内脉体是沿矿区低角度逆冲断裂次级破裂面充填的。矿区地表及深部(400m以下)脉体以陡立为主,矿化较弱。矿区流体的运移具先沿水压直立破裂往上运移,进入剪切带后沿剪切带次级破裂侧向和向上运移,并在剪切带中富集成矿。低温矿物组合脉体穿切高温矿物组合脉体的特征说明脉体形成过程矿区处于隆升构造环境,这对斑岩铜矿成矿有利。 相似文献