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1.
在野外考察的基础上 ,结合所采集的各条断裂之上的覆盖物或断层带物质的热释光 (TL)或电子自旋共振 (ESR)样品年龄 ,对龙门山断裂带北段的晚第四纪活动性进行了分析 ,认为 :后山断裂在第四纪早 -中期曾有过活动 ,晚更新世以来已不再活动 ;中央断裂早更新世或前第四纪是活动的 ;前山断裂在白龙江以北变成一些小的、零星分布的断裂 ,它们在第四纪早期以前有过活动。而已有研究表明龙门山断裂带中段和西南段晚第四纪以来仍在活动。造成龙门山断裂带不同段落新活动时代不同的主要原因 ,可能是区域应力场的变化所导致的活动地块边界的变化。龙门山断裂带的北段现在已不构成活动块体的边界 ,加之岷山隆起对龙门山断裂带东北段的屏障作用 ,使得龙门山断裂带北段活动减弱。而龙门山推覆构造带中南段和岷山隆起构造带共同成为块体持续挤压作用的东界。这为研究青藏高原的运动学及动力学等问题提供了重要信息 相似文献
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营潍断裂带以北西向北京 蓬莱断裂带与之交汇的部位为界分南北两段,北段由辫状交织的两条断裂组成;南段为并列的东西两支断裂,但被黄北、莱北和潍北等北东东向断裂横切成4节。断裂带北段早第三纪水平拉张和垂直差异活动强烈,控制了断陷盆地的发育,晚第三纪—第四纪右旋走滑活动显著。南段本身活动甚弱,但黄北等横向断裂早第三纪水平拉张和垂直差异活动强烈,相应形成了黄北等几个断陷盆地;晚第三纪—第四纪横向断裂仍有活动。断裂带活动具明显的分段性,南段是受横向断裂强烈分割、改造而被“废弃”的一段。断裂带新生代活动具由南部和北部统一向中部迁移的特点,北段还有向东侧迁移的趋势。断裂带地震活动微弱,渤海中部斜穿断裂带分布的北东向地震带,可能是黄河口聊城新生地震构造带向海区延伸的部分 相似文献
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《地震地质》2016,(3)
龙门山断裂带南段第四纪沉积差,断层出露不明显,晚第四纪构造活动性资料零星。为了提高对龙门山断裂带南段构造活动性的认识,探索芦山地震的发震构造,文中在分析龙门山断裂带南段的地貌以及构造演化的基础上,对跨盐井-五龙断裂、大川-双石断裂和芦山盆地的青衣江不同段的6级河流阶地进行了差分GPS连续测量和细致研究,结合对高分辨率航拍影像的地质解译,得到了龙门山断裂带南段青衣江各段的河流阶地横剖面,通过不同河段河流阶地的对比分析,建立了龙门山断裂带南段青衣江河流阶地纵剖面。通过对河流阶地的变形分析,发现龙门山断裂带南段晚第四纪以来,盐井-五龙断裂的平均垂向断错速率为0.6~1.2mm/a,大川-双石断裂没有明显的垂向活动,芦山地震的发震断层控制的山前褶皱最新活动。结合龙门山断裂带南段的地壳深部结构资料和芦山地震的精定位余震资料等,认为芦山地震的发震构造不是大川-双石断裂,而是龙门山断裂带南段的山前盲逆断层和反冲断层。 相似文献
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《地震地质》2017,(4)
为揭示汶川地震前龙门山及其周缘断裂的形变与应力累积状态,文中构建了包含龙门山、龙日坝、岷江和虎牙4条断裂的三维黏弹性有限元模型,以1999—2004年GPS结果为约束,模拟了龙门山断裂带及其周缘区域的形变运动。得到以下结论:1)平行于龙门山断裂带的速度分量主要被龙日坝断裂吸收,垂直于龙门山断裂带的速度分量主要被其自身吸收;岷江和虎牙断裂对龙门山断裂带北段起到一定的屏障作用,导致其北段压缩量明显低于南段。2)沿龙门山断裂带由SW向NE方向延伸,主压应力与断层走向的夹角由接近垂直逐步转至约45°;断层南段挤压、剪切应力累积速率高,且压应力大于剪应力,北段应力累积速率低,压应力与剪应力接近。这与龙门山断裂带SW段中小地震频发、地震活动强烈,NE段偶有小震、地震活动微弱相吻合;也与汶川M_S8.0地震逆冲兼具右旋走滑、芦山M_S7.0地震逆冲破裂的方式相一致。3)假设发生震级、类型相同的地震所需应力积累量相同,那么研究区内岷江断裂、龙门山断裂南段和虎牙断裂破裂以逆冲运动为主,3条断裂的地震复发周期依次变长;龙日坝断裂北段和龙门山断裂北段以逆冲兼具右旋走滑为主,前者地震复发周期短于后者;龙日坝断裂南段则以纯右旋走滑为主,地震复发周期有可能最短。 相似文献
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龙门山北部陕甘川交界三角构造区断裂活动特征研究 总被引:2,自引:0,他引:2
龙门山北部3条不同走向的断裂带所围限的三角地区是我国陕甘川交界地区研究地震活动的重要场所.通过对区内秦岭南缘断裂、 平武—青川断裂、 岷江断裂及虎牙断裂活动特征研究和活动时代分析认为: 秦岭南缘断裂, 包括迭部—舟曲断裂、 武都—康县—略阳断裂及茶店—勉县断裂在晚更新世曾有过活动, 在全新世活动不明显; 龙门山断裂带东北段平武—青川断裂最后一次活动发生在晚更新世, 表现为右旋走滑的逆断裂, 全新世活动不明显; 岷江断裂和虎牙断裂不但在晚更新世活动强烈, 而且在全新世继续活动; 龙门山北部这个三角地区依然是未来地震活动关注的重点地区. 相似文献
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用岷江都江堰—汶川段晚第四纪阶地面的变形量估算了龙门山断裂带中段的滑动速率。岷江及其支流发育3级晚第四纪河流阶地,阶地面的年龄分别约为10,20,50kaBP。阶地纵剖面在茂汶-汶川断裂、北川-映秀断裂和江油-灌县断裂处有明显的垂直变形。断裂活动具有间歇性特点,晚第四纪以来有过3期活动,其起始时间分别为50,20,10kaBP。依据各级阶地面年龄和变形量估算的茂汶-汶川断裂、北川-映秀断裂和江油-灌县断裂晚第四纪逆冲滑动速率分别为0.5,0.6~0.3,0.2mm/a;据阶地走滑位错估算的茂汶-汶川断裂和北川-映秀断裂的晚第四纪右旋走滑速率均约为1mm/a。现代河床之下发育很厚的河流堆积物表明,龙门山的构造抬升经历了较为复杂的过程 相似文献
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岷山断块由岷江断裂和虎牙断裂自西向东的推覆逆掩运动所形成 ,处于我国南北地震带的中段。受区域NWW向主压应力场的控制 ,岷江断裂带第四纪以来表现为明显的推覆逆掩运动并具有一定的左旋走滑分量 ,岷山断块则处于强烈的隆起抬升状态。航片解译及野外地质考察结果表明 ,岷江断裂带由数条次级断裂呈羽列组合而成 ,其中尕米寺 -川盘右阶羽列区的羽列距达3km ,控制了低序次的地震破裂单元。第四纪地貌发育过程及断错地貌研究结果表明 ,岷江断裂晚第四纪以来的平均垂直滑动速率为 0 37~ 0 53mm/a ,水平位错量与垂直位错量大致相当 ;岷山断块第四纪以来的平均隆起速率为 1 5mm/a左右。地震活动特征表明 ,该地区 6级以上强震丛集于强烈活动的断块边界断裂上 ,中强地震及小震发生在新构造隆起区及近东西向断裂带上 ,与断裂的活动性质具有密切的成因联系 相似文献
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《地球物理学进展》2015,(4)
2013年4月20日在龙门山断裂南段发生的芦山M7.0级地震已过去近1年.本文根据四川省地震台网资料和收集的国内外相关历史资料,研讨了巴颜喀拉地块东缘区域龙门山断裂、岷江断裂、虎牙断裂等历史地震活动;分析了龙门山断裂带2008年5月12日汶川8.0级和2013年4月20日芦山7.0级地震余震时空、震源机制及破裂扩展等特征;讨论了巴颜喀拉地块东缘区域的能量释放特征等.结果表明:(1)芦山7.0级地震西南的龙门山断裂南段仍存在尚未破裂的背景性破裂空段;(2)芦山7.0级地震与汶川8.0级地震两余震区之间的空段区存在能量待释放;(3)龙门山断裂中北段(在汶川余震区内)的北川附近存在能量释放不充分的局部区域. 相似文献
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阿拉善地块南缘发育了由5条走向近EW、向西收敛、向东撒开的断裂组成的断裂束,每条断裂长度一般>100km,控制第四纪盆地呈EW向长条状展布,卫片上线性影像清晰,晚第四纪以来表现出左旋走滑活动的特点。断裂束西段的金塔南山断裂与阿尔金断裂带东段的宽滩山段趋于交会,并与文殊山构造隆起之间构成构造转换关系。分析认为金塔南山断裂以及整个阿拉善南缘断裂束是阿尔金断裂左旋运动的东延部分,断裂束在平面上“帚状”的、向东撒开的构造样式有利于走滑运动量的分解、消减和吸收,符合走滑断裂末端的构造特点。阿拉善南缘断裂束的左旋走滑活动有可能是阿尔金断裂带进一步向东扩展的结果,其时代可能发生于早更新世末—中更新世初 相似文献
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ANALYSIS OF EVOLUTION OF THE RIYUESHAN FAULT SINCE LATE PLEISTOCENE USING STRUCTURAL GEOMORPHOLOGY 
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下载免费PDF全文 The northeastern margin of Tibetan plateau is an active block controlled by the eastern Kunlun fault zone, the Qilian Shan-Haiyuan fault zone, and the Altyn Tagh fault zone. It is the frontier and the sensitive area of neotectonic activity since the Cenozoic. There are widespread folds, thrust faults and stike-slip faults in the northeastern Tibetan plateau produced by the intensive tectonic deformation, indicating that this area is suffering the crustal shortening, left-lateral shear and vertical uplift. The Riyueshan Fault is one of the major faults in the dextral strike-slip faults systems, which lies between the two major large-scale left-lateral strike-slip faults, the Qilian-Haiyuan Fault and the eastern Kunlun Fault. In the process of growing and expanding of the entire Tibetan plateau, the dextral strike-slip faults play an important role in regulating the deformation and transformation between the secondary blocks. In the early Quaternary, because of the northeastward expansion of the northeastern Tibetan plateau, tectonic deformations such as NE-direction extrusion shortening, clockwise rotation, and SEE-direction extrusion occurred in the northeastern margin of the Tibetan plateau, which lead to the left-lateral slip movement of the NWW-trending major regional boundary faults. As the result, the NNW-trending faults which lie between these NWW direction faults are developed. The main geomorphic units developed within the research area are controlled by the Riyueshan Fault, formed due to the northeastward motion of the Tibet block. These geomorphic units could be classified as:Qinghai Lake Basin, Haiyan Basin, Datonghe Basin, Dezhou Basin, and the mountains developed between the basins such as the Datongshan and the Riyueshan. Paleo basins, alluvial fans, multiple levels of terraces are developed at mountain fronts. The climate variation caused the formation of the geomorphic units during the expansion period of the lakes within the northeastern Tibetan plateau. There are two levels of alluvial fans and three levels of fluvial terrace developed in the study area, the sediments of the alluvial fans and fluvial terraces formed by different sources are developed in the same period. The Riyueshan Fault connects with the NNW-trending left-lateral strike-slip north marginal Tuoleshan fault in the north, and obliquely connects with the Lajishan thrust fault in the south. The fault extends for about 180km from north to south, passing through Datonghe, Reshui coal mine, Chaka River, Tuole, Ketu and Xicha, and connecting with the Lajishan thrusts near the Kesuer Basin. The Riyueshan Fault consists of five discontinuous right-step en-echelon sub-fault segments, with a spacing of 2~3km, and pull-apart basins are formed in the stepovers.
The Riyueshan Fault is a secondary fault located in the Qaidam-Qilian active block which is controlled by the major boundary faults, such as the East Kunlun Fault and the Qilian-Haiyuan Fault. Its activity characteristics provide information of the outward expansion of the northeastern margin of Tibet. Tectonic landforms are developed along the Riyueshan Fault. Focusing on the distinct geomorphic deformation since late Pleistocene, the paper obtains the vertical displacement along the fault strike by RTK measurement method. Based on the fault growth-linkage theory, the evolution of the Riyueshan Fault and the related kinetic background are discussed. The following three conclusions are obtained:1)According to the characteristics of development of the three-stage 200km-long steep fault scarp developed in the landforms of the late Pleistocene alluvial fans and terraces, the Riyueshan Fault is divided into five segments, with the most important segment located in the third stepover(CD-3); 2)The three-stage displacement distribution pattern of the Riyueshan Fault reveals that the fault was formed by the growths and connections of multiple secondary faults and is in the second stage of fault growth and connection. With CD-3 as the boundary, the faults on the NW side continue to grow and connect; the fault activity time on the SE side is shorter, and the activity intensity is weaker; 3)The extreme value of the fault displacement distribution curve indicates the location of strain concentration and stress accumulation. With the stepover CD-3 as the boundary, the stress and strain on NW side are mainly concentrated in the middle and fault stepovers. The long-term accumulation range of stress on the SE side is relatively dispersed. The stress state may be related to the counterclockwise rotation inside the block under the compression of regional tectonic stress. 相似文献
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STUDY ON THE LATEST ACTIVITY OF WUYUNSHAN-HEFEI FAULT IN HEFEI BASIN,THE WESTERN BRANCH OF THE TANLU FAULT ZONE 下载免费PDF全文
下载免费PDF全文 ZHENG Ying-ping YANG Xiao-ping SHU Peng LU Shuo FANG Liang-hao SHI Jin-hu HUANG Xiong-nan LIU Chun-ru 《地震地质》1979,42(1):50-64
Tanlu fault zone is the largest strike-slip fault system in eastern China. Since it was discovered by aeromagnetics in 1960s, it has been widely concerned by scholars at home and abroad, and a lot of research has been done on its formation and evolution. At the same time, the Tanlu fault zone is also the main seismic structural zone in China, with an obvious characteristic of segmentation of seismicity. Major earthquakes are mostly concentrated in the Bohai section and Weifang-Jiashan section. For example, the largest earthquake occurring in the Bohai section is M7.4 earthquake, and the largest earthquake occurring in the Weifang-Jiashan section is M8.5 earthquake. Therefore, the research on the active structure of the Tanlu fault zone is mainly concentrated in these two sections. With the deepening of research, some scholars carried out a lot of research on the middle section of Tanlu fault zone, which is distributed in Shandong and northern Jiangsu Province, including five nearly parallel fault systems, i.e. Changyi-Dadian Fault(F1), Baifenzi-Fulaishan Fault(F2), Yishui-Tangtou Fault(F3), Tangwu-Gegou Fault(F4) and Anqiu-Juxian Fault(F5). They find that the faults F3 and F5 are still active since the late Quaternary. In recent years, we have got a further understanding of the geometric distribution, active age and active nature of Fault F5, and found that it is still active in Holocene. At the same time, the latest research on the extension of F5 into Anhui suggests that there is a late Pleistocene-Holocene fault existing near the Huaihe River in Anhui Province.
The Tanlu fault zone extends into Anhui Province and the extension section is completely buried, especially in the Hefei Basin south of Dingyuan. At present, there is little research on the activity of this fault segment, and it is very difficult to study its geometric structure and active nature, and even whether the fault exists has not been clear. Precisely determining the distribution, active properties and the latest active time of the hidden faults under urban areas is of great significance not only for studying the rupture behavior and segmentation characteristics of the southern section of the Tanlu fault zone, but also for providing important basis for urban seismic fortification. By using the method of shallow seismic prospecting and the combined drilling geological section, this paper carries out a detailed exploration and research on the Wuyunshan-Hefei Fault, the west branch fault of Tanlu fault zone buried in Hefei Basin. Four shallow seismic prospecting lines and two rows of joint borehole profiles are laid across the fault in Hefei urban area from north to south. Using 14C, OSL and ESR dating methods, ages of 34 samples of borehole stratigraphic profiles are obtained. The results show that the youngest stratum dislocated by the Wuyunshan-Hefei Fault is the Mesopleistocene blue-gray clay layer, and its activity is characterized by reverse faulting, with a maximum vertical offset of 2.4m. The latest active age is late Mesopleistocene, and the depth of the shallowest upper breaking point is 17m. This study confirms that the west branch of Tanlu fault zone cuts through Hefei Basin and is still active since Quaternary. Its latest activity age in Hefei Basin is late of Middle Pleistocene, and the latest activity is characterized by thrusting. The research results enrich the understanding of the overall activity of Tanlu fault zone in the buried section of Hefei Basin and provide reliable basic data for earthquake monitoring, prediction and earthquake damage prevention in Anhui Province. 相似文献
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LATE QUATERNARY ACTIVITY OF THE CENTRAL SEGMENT OF THE DARI FAULT AND RESTUDY OF THE SURFACE RUPTURE ZONE OF THE 1947 M73/4 DARI EARTHQUAKE,QINGHAI PROVINCE 下载免费PDF全文
下载免费PDF全文 Bayan Hara Block is one of the most representative active blocks resulting from the lateral extrusion of Tibet Plateau since the Cenozoic. Its southern and northern boundary faults are characterized by typical strike-slip shear deformation. Its eastern boundary is blocked by the Yangze block and its horizontal movement is transformed into the vertical movement of the Longmen Shan tectonic belt, leading to the uplift of the Longmen Shan Mountains and forming a grand geomorphic barrier on the eastern margin of the Tibet Plateau. A series of large earthquakes occurred along the boundary faults of the Bayan Hara Block in the past twenty years, which have attracted attention of many scholars. At present, the related studies of active tectonics on Bayan Hara Block are mainly concentrated on the boundary faults, such as Yushu-Ganzi-Xianshuihe Fault, East Kunlun Fault and Longmen Shan Fault. However, there are also some large faults inside the block, which not only have late Quaternary activity, but also have tectonic conditions to produce strong earthquake. These faults divide the Bayan Hara Block into some secondary blocks, and may play important roles in the kinematics and dynamics mechanism of the Bayan Hara Block, or even the eastern margin of the Tibet Plateau. The Dari Fault is one of the left-lateral strike-slip faults in the Bayan Hara Block. The Dari Fault starts at the eastern pass of the Kunlun Mountains, extends eastward through the south of Yalazela, Yeniugou and Keshoutan, the fault strike turns to NNE direction at Angcanggou, then turns to NE direction again at Moba town, Qinghai Province, and the fault ends near Nanmuda town, Sichuan Province, with a total length of more than 500km. The fault has been considered to be a late Quaternary active fault and the 1947 M73/4 Dari earthquake was produced by its middle segment. But studies on the late Quaternary activity of the Dari Fault are still weak. The previous research mainly focused on the investigation of the surface rupture and damages of the 1947 M73/4 Dari earthquake. However, there were different opinions about the scale of the M73/4 earthquake surface rupture zone. Dai Hua-guang(1983)thought that the surface rupture of the earthquake was about 150km long, but Qinghai Earthquake Agency(1984) believed that the length of surface rupture zone was only 58km. Based on interpretation of high-resolution images and field investigations, in this paper, we studied the late Quaternary activity of the Dari Fault and the surface rupture zone of the 1947 Dari earthquake. Late Quaternary activity in the central segment of the Dari Fault is particularly significant. A series of linear tectonic landforms, such as fault trough valley, fault scarps, fault springs and gully offsets, etc. are developed along the Dari Fault. And the surface rupture zone of the 1947 Dari earthquake is still relatively well preserved. We conducted a follow-up field investigation for the surface rupture zone of the 1947 Dari earthquake and found that the surface rupture related to the Dari earthquake starts at Longgen village in Moba town, and ends near the northwest of the Yilonggounao in Jianshe town, with a length of about 70km. The surface rupture is primarily characterized by scarps, compressional ridges, pull-apart basins, landslides, cleavage, and the coseismic offset is about 2~4m determined by a series of offset gullies. The surface rupture zone extends to the northwest of Yilonggounao and becomes ambiguous. It is mainly characterized by a series of linear fault springs along the surface rupture zone. Therefore, we suggest that the surface rupture zone of the 1947 Dari earthquake ends at the northwest of Yilonggounao. In summary, the central segment of the Dari Fault can be characterized by strong late Quaternary activity, and the surface rupture zone of the 1947 Dari earthquake is about 70km long. 相似文献
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北西走向的桥头集-东关断裂与郯庐断裂带南段相交切,横跨合肥盆地及其东缘的隆起区,在合肥盆地内呈隐伏状态。本研究跨桥头集-东关断裂合肥盆地段布设3条浅层地震勘探测线,揭示断裂浅部构造特征。解译出的FP1、FP2和FP3断层性质相同,倾向一致,上断点深度相近,反映出桥头集-东关断裂合肥盆地段是一条走向NW、倾向SW、具有逆断分量的断裂。3条浅层地震反射剖面中第四系的底界面反射波组TQ呈连续近水平展布,表明桥头集-东关断裂两侧的第四系厚度无明显变化。在浅震剖面解译的基础上,布设了1条跨断层钻孔联合剖面,剖面揭露出的第四系没有被错动。结合本区第四系地层发育情况及钻孔地层年龄分析,认为桥头集-东关断裂中更新世以来不活动。根据本文探测结果,尚不能排除桥头集-东关断裂早更新世有一定的弱活动。 相似文献
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The Hetao depression zone, located to the north of Ordos block, is a complex depression basin that consists of two sub-uplifts and three sub-depressions. The depression zone is subject to the regional extensional stress field driven by the Indo-Asian continental collision and the westward subduction of the Pacific Plate. The Baotou uplift that separates the Baiyanhua sub-depression and Huhe sub-depression is mainly composed of Archean gneiss and is overlaid by Quaternary sedimentary strata. The two sub-depressions are bordered by the Wula Mountains and Daqing Mountains to the north, respectively. The bedrock exhumed in Wula Mountains and Daqing Mountains consists mostly of Precambrian granitic gneiss, and the piedmont depressions are infilled by thick Cenozoic strata. The Wulashan piedmont fault and Daqingshan piedmont fault extend along the range front of Wula Mountains and Daqing Mountains, respectively. The subsidence is controlled by the two boundary faults. Previous studies have preliminarily documented the characteristics of the northwest boundary fault of Baotou uplift. Combining shallow seismic exploration, active fault mapping, and geological drilling, this paper presents a detailed study on the tectonic characteristics of the Baotou uplift.
The shallow seismic exploration reveals that the Baotou uplift is an asymmetrical wedge with a steep southeast wing and a gentle dipping northwest wing. The Baotou uplift is wider in the northeastern part and narrows down towards the southwest. In seismic profiles, the Baiyanhua sub-depression and the Huhe sub-depression manifest as asymmetric dustpan-like depressions with south-dipping controlling faults. Baotou uplift is bounded by the Xishawan-Xingsheng Fault to the northwest and Daqingshan piedmont fault to the southeast. The two faults exhibit significant difference in many aspects, such as fault geometry, fault displacement, the latest active time, and so on. The southeast boundary fault of Baotou uplift is the Baotou section of the Daqingshan piedmont fault which is a Holocene active fault and the major boundary fault of Huhe sub-depression. East of Wanshuiquan, the fault strikes EW-NEE; west of Wanshuiquan, the strike changes to NW. The Daqingshan piedmont fault appears as a south-dipping listric fault in seismic profiles whose dip decreases with depth and cuts through all the sedimentary strata in Huhe sub-depression; the fault extends along the late Pleistocene lacustrine platform at surface with prominent geomorphological evidences. The Xishawan-Xingsheng Fault is a buried high-angle normal fault that mainly dips to the northwest and strikes NE. The fault strike changes to NNE at the eastern tip. Based on the results of seismic exploration and geological drilling, the Xishawan-Xingsheng buried fault is an early to middle Pleistocene Fault capped by late Pleistocene lacustrine strata. We reckon that the Xishawan-Xingsheng Fault is one of the synthetic faults that dip towards the main boundary fault of Baiyanhua sub-depression.
Similarities in lithology, geometry, and structural characteristics of south boundary faults all indicate that Baotou uplift is the western extension of Daqing Mountains. Multiple factors may contribute to the formation of Baotou uplift, such as tectonic subsidence and the development of large-scale river system and mega-lake. We suggest that the upwelling of asthenosphere may play a primary role in the evolution of Wulanshan piedmont fault and Daqingshan piedmont fault. Separated by the Baotou uplift, the Wulashan piedmont fault and Daqingshan piedmont fault can be regarded as independent seismogenic faults. The Hetao depression zone is featured by complex inner structures, and many scientific issues are subject to further researches. Thus, more attention should be paid to the secondary structures within the depression zone for a better understanding on the formation and evolution of Hetao depression zone. 相似文献
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USING DEFORMED FLUVIALTERRACES OF THE QINGYIJIANG RIVER TO STUDY THE TECTONIC ACTIVITY OF THE SOUTHERN SEGMENT OF LONGMENSHAN FAULT ZONE 下载免费PDF全文
下载免费PDF全文 On 20 April 2013, a destructive earthquake, the Lushan MS7.0 earthquake, occurred in the southern segment of the Longmenshan Fault zone, the eastern margin of the Tibetan plateau in Sichuan, China. This earthquake did not produce surface rupture zone, and its seismogenic structure is not clear. Due to the lack of Quaternary sediment in the southern segment of the Longmenshan fault zone and the fact that fault outcrops are not obvious, there is a shortage of data concerning the tectonic activity of this region. This paper takes the upper reaches of the Qingyijiang River as the research target, which runs through the Yanjing-Wulong Fault, Dachuan-Shuangshi Fault and Lushan Basin, with an attempt to improve the understanding of the tectonic activity of the southern segment of the Longmenshan fault zone and explore the seismogenic structure of Lushan earthquake.
In the paper, the important morphological features and tectonic evolution of this area were reviewed. Then, field sites were selected to provide profiles of different parts of the Qingyijiang River terraces, and the longitudinal profile of the terraces of the Qingyijiang River in the south segment of the Longmenshan fault zone was reconstructed based on geological interpretation of high-resolution remote sensing images, continuous differential GPS surveying along the terrace surfaces, geomorphic field evidence, and correlation of the fluvial terraces.
The deformed longitudinal profile reveals that the most active tectonics during the late Quaternary in the south segment of the Longmenshan Fault zone are the Yanjing-Wulong Fault and the Longmenshan range front anticline. The vertical thrust rate of the Yanjing-Wulong Fault is nearly 0.6~1.2mm/a in the late Quaternary. The tectonic activity of the Longmenshan range front anticline may be higher than the Yanjing-Wulong Fault. Combined with the relocations of aftershocks and other geophysical data about the Lushan earthquake, we found that the seismogenic structure of the Lushan earthquake is the range front blind thrust and the back thrust fault, and the pop-up structure between the two faults controls the surface deformation of the range front anticline. 相似文献
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安宁河断裂紫马跨一带晚第四纪地貌变形与断层位移速率 总被引:7,自引:6,他引:1
紫马跨一带是安宁河断裂北段晚第四纪断错地层地貌序列保存最好的地区,通过数字影像分析、全站仪实测和探槽开挖,对该地点断错现象进行细致研究,获得了晚全新世以来的左旋位移速率为6·2mm/a,垂直位移速率1·4mm/a;距今约10ka以来的平均左旋位移速率3·6~4·0mm/a,垂直位移速率约为1·1mm/a;距今约20ka以来的左旋位移速率为3·8~4·2mm/a,垂直位移速率最小为0·9mm/a。断层水平和垂直位移速率的比例约为4∶1。断层位移速率在时间分布上的变化与古地震研究的丛集复发特征有较好的一致性,反映断裂的活动强度存在强弱活动的交替现象 相似文献
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THE CRUSTAL SHALLOW STRUCTURES AND FAULT ACTIVITY DETECTION IN XINYI SECTION OF TAN-LU FAULT ZONE 下载免费PDF全文
下载免费PDF全文 GU Qin-ping XU Han-gang YAN Yun-xiang ZHAO Qi-guang LI Li-mei MENG Ke YANG Hao WANG Jin-yan JIANG Xin MA Dong-wei 《地震地质》1979,42(4):825-843
The Tan-Lu fault zone is the largest active tectonic zone in eastern China, with a complex history of formation and evolution, and it has a very important control effect on the regional structure, magmatic activity, the formation and distribution of mineral resources and modern seismic activity in eastern China. Xinyi City has a very important position as a segmental node in the Shandong and Suwan sections of the Tan-Lu fault zone. Predecessors have conducted research on the spatial distribution, occurrence and activity characteristics of the shallow crustal faults in the Suqian section of the Tan-Lu belt, and have obtained some new scientific understandings and results. However, due to different research objectives or limitations of research methods, previous researches have either focused on the deep crustal structure, or targeted on the Suqian section or other regions. However, the structural style and deep-shallow structural association characteristics of Xinyi section of Tan-Lu belt have not been well illustrated, nor its activity and spatial distribution have been systematically studied. In order to investigate the shallow crustal structure features, the fault activities, the spatial distribution and the relationship between deep and shallow structures of the Xinyi section of the Tan-Lu Fault, we used a method combining mid-deep/shallow seismic reflection exploration and first-break wave imaging. Firstly, a mid-deep seismic reflection profile with a length of 33km and a coverage number greater than 30 was completed in the south of Xinyi City. At the same time, using the first arrival wave on the common shot record, the tomographic study of the shallow crust structure was carried out. Secondly, three shallow seismic reflection profiles and one refraction tomography profile with high resolution across faults were presented. The results show that the Xinyi section of Tan-Lu fault zone is a fault zone composed of five concealed main faults, with a structural pattern of “two grabens sandwiched by a barrier”. The five main faults reveal more clearly the structural style of “one base between two cuts” of the Tan-Lu fault zone. From west to east, the distribution is as follows: on the west side, there are two high-angle faults, F4 and F3, with a slot-shaped fault block falling in the middle, forming the western graben. In the middle, F3 and F2, two normal faults with opposite dip directions, are bounded and the middle discontinuity disk rises relatively to form a barrier. On the east side, F2 and F1, two conjugate high-angle faults, constitute the eastern graben. The mid-deep and shallow seismic reflection profiles indicate that the main faults of the Xinyi section of Tan-Lu fault zone have a consistent upper-lower relationship and obvious Quaternary activities, which play a significant role in controlling the characteristics of graben-barrier structure and thickness of Cenozoic strata. The shape of the reflective interface of the stratum and the characteristics of the shallow part of the fault revealed by shallow seismic reflection profiles are clear. The Mohe-Lingcheng Fault, Xinyi-Xindian Fault, Malingshan-Chonggangshan Fault and Shanzuokou-Sihong Fault not only broke the top surface of the bedrock, but also are hidden active faults since Quaternary, especially the Malingshan-Chonggangshan Fault which shows strong activity characteristics of Holocene. The results of this paper provide a seismological basis for an in-depth understanding of the deep dynamics process of Xinyi City and its surrounding areas, and for studying the deep-shallow tectonic association and its activity in the the Xinyi section of the Tan-Lu Fault. 相似文献