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在位场数据处理及解释中,断裂的提取至关重要,因此,如何更有效提取边界信息,压制数据中的噪声成为解释人员重点研究目标.本文通过讨论用于识别重力断裂构造模型的导数方法与Daubechies小波分析方法在信号分析过程中的异同,证明了这两种方法在断裂识别中的有效性.提出将这两种断裂识别方法相结合进行断裂识别的新方法.通过对漠河盆地高精度重力剖面测线数据使用经典断裂反演方法和Daubechies多尺度小波分析相结合的方法划分出10条断裂构造,并在漠河盆地中依据平面重力异常利用上述方法识别出四组断裂构造,详细分析了由剖面数据及平面数据获得的各个断裂的构造特征.通过在漠河盆地高精度实测数据中的应用,多尺度小波分析与经典方法相结合的断裂构造识别方法可有效的避免单用经典方法时产生的多个离散点的影响及对断裂位置划分的干扰.该方法可明显去除一些不收敛的反演点位,使断裂图的清晰度得到大幅度提高. 相似文献
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断裂构造的遥感识别、提取方法和技术具有非常重要的应用和研究价值。随着遥感及相关技术的快速发展,断裂构造的遥感解译方法也取得了较大的进展。简要叙述了断裂构造判读标志及遥感影像的选择与合成。 相似文献
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汤郎-易门断裂位于青藏高原东南缘,走向近南北,按地貌特征及区域构造背景可将其划分为北段(营盘村-插甸断裂)、中段(插甸-碧城断裂)及南段(碧城-易门断裂)。针对汤郎-易门断裂构造地貌差异,利用30 m分辨率的DEM数据,基于GIS技术提取与断裂活动相关的水系,并计算其陡峭指数,结合野外考察及遥感影像讨论断裂在不同分段的活动习性与地貌特征。研究发现,区域内降水及基岩抗风化能力对亚流域陡峭指数的影响较小,认为陡峭指数能够较好地反映汤郎-易门断裂的垂直构造运动。陡峭指数显示,断裂走向呈两端高、中间低的特点,其分段性与前人划分结果具有较好一致性,所表征的基岩垂直活动性差异可作为断裂带活动分段的依据。断裂带东西侧陡峭指数在不同分段上表现出差异性,北段断裂东西侧陡峭指数显示出东、西向差异性抬升不显著,其与地貌上断裂北段表现的左旋走滑运动一致,以水平运动为主;断裂中段及南段陡峭指数在东西侧表现出东高西低的特点,显示东侧较西侧基岩抬升更快,可能以垂直差异运动为主。 相似文献
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《地震地质》2016,(2)
疏勒河流域盆地位于祁连山西段,跨越了该区多条不同方向和不同性质的活动断裂带,其所呈现的地貌特征反映了该区最新构造活动的信息。文中基于GIS空间分析技术,利用SRTM-3数字高程模型(DEM)数据,系统提取了疏勒河流域及其4个亚流域盆地的面积-高程积分曲线、疏勒河水系的Hack剖面以及河流坡降指标(SL),并对整个流域地形做了坡谱分析,获得了疏勒河流域的地貌特征。研究表明,疏勒河的流域地貌发育受到该区的阿尔金断裂、昌马断裂、托勒南山断裂以及疏勒南山断裂等强烈构造活动和区域岩性差异的影响,坡度以0°~35°的区段为主;整个流域盆地处于河流发育的"壮年期";构造活动是造成河流纵剖面发生改变的最主要因素,局部河段同时还受到岩性因素的控制和影响。这表明在活跃的造山带内部,河流地貌的发育过程中,活动断裂的构造作用是重要的控制因素。 相似文献
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通过Arcgis catlog建立延怀盆地地震和活动断裂基础数据库,运用GIS软件环境的缓冲区、空间叠加及统计等分析方法,对延怀盆地内部地震活动与活动断裂关系进行研究,结果证明:中小地震活动主要沿怀涿盆地北缘断裂和延矾盆地北缘断裂分布;约83.7%的地震发生在以10 km为半径的断裂缓冲区内;在正断层缓冲区内,单位地震数较高。结合活动构造特征,分析认为,延怀盆地在全新世以来受拉张应力场控制作用,中小地震活动集中分布在盆地一侧,且靠近控制盆地的主控边界断裂。 相似文献
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目前虽然有许多种方法可以进行构造裂缝预测,但由于碳酸盐岩发育区裂缝发育的复杂性,需要综合研究构造裂缝定量预测的新方法.本文以哈萨克斯坦扎纳若尔碳酸盐岩凝析油田为研究和应用对象,提出了基于GIS系统的构造裂缝综合分析技术,通过构造DEM滤波分析、综合曲率分析、裂缝地形因子分析以及DEM构造应力场分析,提取与裂缝有关的构造起伏变化和侵蚀程度指标,对于碳酸盐岩储层利用DEM进行古水文地质条件分析,研究古地貌侵蚀和沉积的空间分布情况.根据构造应力场信息,综合分析不同构造部位岩层发生破裂的可能性及破裂程度,预测区域裂缝和局部构造裂缝发育带、发育程度及发育方向,并取得了不错的预测效果. 相似文献
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祁漫塔格北缘断裂处于青藏高原内部造山带地区,其构造活动反映了青藏高原的构造演化特征。本文采用活动构造和构造地貌相结合的研究方法,对该断裂的活动性进行初步分析研究。首先采用航卫片解译和野外调查,发现该断裂断错了山前全新世冲洪积扇,形成的断层陡坎高度在1.5~2.5m。通过扩散方程,并参考前人研究结果,认为祁漫塔格北缘断裂晚第四纪的抬升速率初步限定在1~2mm/a。我们基于数字高程模型提取的地形高程纵剖面和面积-高程积分,其结果也支持祁漫塔格北缘存在构造活动。 相似文献
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涉县断裂为太行山隆起区内涉县盆地的控盆构造,走向由NE转为近EW向,倾向NW/N,中部在井店东被EW向断裂错断,是控制涉县盆地的一组断裂。本文采用地质地貌调查、河流阶地分析和地质测年等方法,研究了涉县断裂晚第四纪活动特征。研究发现,涉县断裂带由多组断裂构成,带宽约200m,在清漳河两侧表现为山前的陡崖地貌、基岩破碎变形带,具有正断兼走滑特征,在基岩变形带上部发育走向NNE向和NWW向次级滑动面,次级滑动面错断第四系黄土,最新活动到晚更新世;断裂在盆地区通过,地表形成低缓陡坎,断裂错断Q2-3地层,表现为上陡下缓的正断层。通过对涉县断裂两侧清漳河河流阶地、夷平面和地层年龄综合分析,估算涉县断裂晚更新世以来平均垂直滑动速率为0.06~0.08mm/a,中更新世以来平均垂直滑动速率为0.22~0.34mm/a,垂直差异活动主要发生于中更新世期间。 相似文献
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西秦岭临潭-宕昌断裂第四纪最新活动特征 总被引:2,自引:0,他引:2
临潭-宕昌断裂是西秦岭造山带内一条重要的分支断裂,其最新活动特征是分析西秦岭构造变形的重要依据。临潭-宕昌断裂的新构造活动强烈,中强地震频繁,但目前对于断裂的新活动特征研究程度较低,未见有其全新世活动地质地貌证据的报道。文中基于遥感解译、宏观地貌分析研究断裂的长期活动表现和分段性;同时通过地质地貌考察、无人机摄影测量、差分GPS和放射性碳测年等方法定量研究断裂的新活动特征;最后基于研究结果探讨了断裂及附近区域的地震危险性和区域构造变形。结果表明:根据断层迹线收敛程度和宏观地貌差异,可将临潭-宕昌断裂分为西、中、东3段;断裂的运动性质以左旋走滑为主,兼具逆冲分量,左旋走滑使洮河及其支流、冲沟和山脊等发生同步左旋拐弯,最大左旋位移可达3km,逆冲分量使新近纪盆地边缘和内部形成300~500m的垂向位移;断裂的最新活动时代为全新世,限定了1次2 090~7 745a BP(置信度为2σ)的全新世古地震事件;全新世早期以来,临潭-宕昌断裂东段主干断裂的左旋走滑速率为0.86~1.65mm/a,垂直滑动速率为0.05~0.10mm/a。临潭-宕昌断裂分配了约2mm/a的左旋走滑分量,是东昆仑-西秦岭阶区变形分配的关键断裂之一。 相似文献
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西藏和西南三江地区是青藏地区断裂构造最为复杂区域,历经数十年研究,对该区断裂构造的认识仍存在分歧.笔者以最新实测航磁数据并结合重力资料为基础,从重、磁场特征与地质构造研究相结合角度出发,新编制了西藏及西南三江地区的断裂构造格架图.研究结果表明,在西南三江流域的金沙江深断裂、澜沧江深断裂和怒江深断裂自南向北西延伸,没有与西藏地区的近东西向断裂呈弧形连接,而是一组独立存在的北西向断裂,这是在特提斯断裂系统中新发现的一组北西向断裂,它与发育在西藏地区的近东西向断裂分属于不同的断裂系,与前人提出的金沙江缝合带、龙木错—澜沧江缝合带和班公湖—怒江缝合带的走向呈北西—近东西向弧形分布特征的看法存在差异.这组断裂的发现改变了对西藏—西南三江地区断裂构造格架的认识,这为今后大地构造研究提出新的启示.文章重点展现西南三江(金沙江、澜沧江、怒江)深断裂带在重、磁场上的西延状况,并探讨了西南三江深断裂与西藏地区近东西向深断裂呈相交关系特征,同时也表明重、磁资料用于断裂构造的研究具有重要意义. 相似文献
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The morphotectonic framework of the Central Apennines is given by faulted blocks bounded by normal faults, mostly trending NW–SE, NNW–SSE and NE–SW, which cut previous compressive structures. Such a structural setting is consistent with the focal mechanisms of the earthquakes which often occur in this area. In this paper, three lithologically different normal fault-generated mountain fronts are analysed in order to assess the relations between their geomorphic features and active tectonics. They border the Norcia depression (Sibillini Mts, Umbria), the Amatrice–Campotosto plateau (Laga Mts, Lazio) and the Fucino basin (Marsica Mts, Abruzzi). The Norcia depression is bounded by a N20°W trending normal fault to the east and by a parallel antithetic fault to the west. The main fault has a 1000 m throw and gives rise to a wide fault escarpment, characterized by: (1) sharp slope breaks due to low angle gravity faults; (2) important paleolandslides; and (3) several fault scarplets on the piedmont belt affecting Quaternary deposits. The Amatrice–Campotosto plateau is delimited by the western slope of Mt Gorzano which runs along a N20°W trending normal fault having a 1500m throw. Minor parallel faults dislocate Quaternary landforms. Large-scale massmovements also occur here. The Fucino basin was struck by the 1915 Avezzano earthquake (I=XI MCS) which produced extensive surface faulting along two parallel NW trending normal fault escarpments on the eastern border of the basin. There is paleoseismic evidence including buried gravity graben in Late Glacial gravels and tectonic dip-slip striations on Holocene calcitic crusts covering bedrock normal fault planes. These data suggest that active extensional tectonics plays a major role in the slope morphogenesis of the Central Apennines and they indicate the importance of geomorphic analysis in seismic zonation of this area. 相似文献
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LIMITATION OF CURRENT TECTONIC DEFORMATION MODES IN THE WESTERN MARGIN OF ORDOS BASED ON SEISMIC ACTIVITY CHARACTERISTICS 
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下载免费PDF全文 ZHAN Hui-li ZHANG Dong-li HE Xiao-hui SHEN Xu-zhang ZHENG Wen-jun LI Zhi-gang 《地震地质》1979,42(2):346-365
Due to the interaction between the Tibetan plateau, the Alxa block and the Ordos block, the western margin of Ordos(33.5°~39°N, 104°~108°E)has complex tectonic features and deformation patterns with strong tectonic activities and active faults. Active faults with different strikes and characteristics have been developed, including the Haiyuan Fault, the Xiangshan-Tianjingshan Fault, the Liupanshan Fault, the Yunwushan Fault, the Yantongshan Fault, the eastern Luoshan Fault, the Sanguankou-Niushoushan Fault, the Yellow River Fault, the west Qinling Fault, and the Xiaoguanshan Fault.
In this study, 7 845 earthquakes(M≥1.0)from January 1st, 1990 to June 30th, 2018 were relocated using the double-difference location algorithm, and finally, we got valid locations for 4 417 earthquakes. Meanwhile, we determined focal mechanism solutions for 54 earthquakes(M≥3.5)from February 28th, 2009 to September 2nd, 2017 by the Cut and Paste(CAP)method and collected 15 focal mechanism solutions from previous studies. The spatial distribution law of the earthquake, the main active fault geometry and the regional tectonic stress field characteristics are studied comprehensively.
We found that the earthquakes are more spatially concentrated after the relocation, and the epicenters of larger earthquakes(M≥3.5) are located at the edge of main active faults. The average hypocenter depth is about 8km and the seismogenic layer ranges from 0 to 20km. The spatial distributions and geometry structures of the faults and the regional deformation feature are clearly mapped with the relocated earthquakes and vertical profiles. The complex focal mechanism solutions indicate that the arc-shaped tectonic belt consisting of Haiyuan Fault, Xiangshan-Tianjingshan Fault and Yantongshan Fault is dominated by compression and torsion; the Yellow River Fault is mainly by stretching; the west Qinling Fault is characterized by shear and compression. The structural properties of the fault structure are dominated by strike-slip and thrust, with a larger strike-slip component. The near-north-south Yellow River Fault is characterized by high angle NW dipping and normal fault motion.
Based on small earthquake relocation and focal mechanism solution results, and in combination with published active structures and geophysical data in the study area, it is confirmed that the western margin of Ordos is affected by the three blocks of the Tibetan plateau, the Alax and the Ordos, presenting different tectonic deformation modes, and there are also obvious differences in motion among the secondary blocks between the active faults. The area south of the Xiangshan-Tianjingshan Fault has moved southeastward since the early Quaternary; the Yinchuan Basin and the block in the eastern margin of the Yellow River Fault move toward the SE direction. 相似文献
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XU Bin-bin ZHANG Dong-li ZHANG Pei-zhen ZHENG Wen-jun BI Hai-yun TIAN Qing-ying ZHANG Yi-peng XIONG Jian-guo LI Zhi-gang 《地震地质》2019,41(3):587-602
Slip rate is one of the most important parameters in quantitative research of active faults. It is an average rate of fault dislocation during a particular period, which can reflect the strain energy accumulation rate of a fault. Thus it is often directly used in the evaluation of seismic hazard. Tectonic activities significantly influence regional geomorphic characteristics. Therefore, river evolution characteristics can be used to study tectonic activities characteristics, which is a relatively reliable method to determine slip rate of fault. Based on the study of the river geomorphology evolution process model and considering the influence of topographic and geomorphic factors, this paper established the river terrace dislocation model and put forward that the accurate measurement of the displacement caused by the fault should focus on the erosion of the terrace caused by river migration under the influence of topography. Through the analysis of the different cases in detail, it was found that the evolution of rivers is often affected by the topography, and rivers tend to migrate to the lower side of the terrain and erode the terraces on this side. However, terraces on the higher side of the terrain can usually be preserved, and the displacement caused by faulting can be accumulated relatively completely. Though it is reliable to calculate the slip rate of faults through the terrace dislocation on this side, a detailed analysis should be carried out in the field in order to select the appropriate terraces to measure the displacement under the comprehensive effects of topography, landform and other factors, if the terraces on both sides of the river are preserved. In order to obtain the results more objectively, we used Monte Carlo method to estimate the fault displacement and displacement error range. We used the linear equation to fit the position of terrace scarps and faults, and then calculate the terrace displacement. After 100, 000 times of simulation, the fault displacement and its error range could be obtained with 95%confidence interval. We selected the Gaoyan River in the eastern Altyn Tagh Fault as the research object, and used the unmanned air vehicle aerial photography technology to obtain the high-resolution DEM of this area. Based on the terrace evolution model proposed in this paper, we analyzed the terrace evolution with the detailed interpretation of the topography and landform of the DEM, and inferred that the right bank of the river was higher than the left bank, which led to the continuous erosion of the river to the left bank, while the terraces on the right bank were preserved. In addition, four stages of fault displacements and their error ranges were obtained by Monte Carlo method. By integrating the dating results of previous researches in this area, we got the fault slip rate of(1.80±0.51)mm/a. After comparing this result with the slip rates of each section of Altyn Tagh Fault studied by predecessors, it was found that the slip rate obtained in this paper is in line with the variation trend of the slip rate summarized by predecessors, namely, the slip rate gradually decreases from west to east, from 10~12mm/a in the middle section to about 2mm/a at the end. 相似文献
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塔里木西缘明尧勒活动背斜两翼河流阶地面上多处发育活动弯滑断层陡坎。这些断坎主要分布在活动轴面附近较陡的等斜岩层(地层倾角分别为74°~89°、18°~20°和45°~60°)一翼,往往成排发育在距活动轴面50~1 200m范围内,宽90~1 000m,长40~950m,随着离活动轴面的距离加大弯滑断层陡坎规模渐小。同一阶地面上发育的弯滑断层陡坎几乎以等间距或间距倍数关系产出。这些断坎走向与下伏基岩地层走向一致,基岩地层大多为中-厚层块状砂岩或粉砂岩互层,岩层间力学性质差异较小。明尧勒背斜南翼克孜勒苏河北岸T3阶地面废弃以来,单条弯滑断层的地表最大缩短速率为0.31mm/a,地表最大抬升速率为0.34mm/a。这些弯滑断层的活动具有重复性和新生性。 相似文献
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In this paper, progress in strain study of blocks and faults by GPS data are discussed, and the concept that active structures between blocks are the main body of crustal strain is clarified. By energy transfer principle of elastic mechanics, the relation between strain around faults and tectonic force on fault surfaces is set up and main body element model of crustal strain is constructed. Finally, the relation between mechanical evolution of model and seismogenic process of Kunlun earthquake (Ms=8.1) is discussed by continuous GPS data of datum stations. The result suggests that the relatively relaxed change under background of strong compressing and shearing may help to trigger moderate-strong earthquakes. 相似文献
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STUDY ON TANGSHAN-HEJIAN-CIXIAN EARTHQUAKE FAULT ZONE BY SHALLOW SEISMIC EXPLORATION METHOD 下载免费PDF全文
下载免费PDF全文 The location of the buried faults, the fault broken layers and the depth of breakpoints in the Tangshan-Hejian-Cixian seismotectonic zone are not clear. We implemented 4 shallow seismic exploration profiles on the Daming Fault, Cangxi Fault, and Dachengdong Fault. Line DZ1 is located on the Daming Fault in the southeast of Daming County. Five breakpoints were dectectd, which are all normal faults, with depths of 95~125m and displacements about 6~12m, offsetting late Pleistocene but not the Holocene. Line DZ2 is located in the east of Xianxian County to dectect the Cangxi Fault. Three breakpoints were detected, all are normal faults, with depths of 170~190m and displacements about 7~10m. The upper breakpoints of the three faults cut the middle Pleistocene. The lines DZ3 and DZ4 are located in the west of Litan Town, Dacheng County. Four breakpoints were detected, with the upper breakpoint depth of 120~130m and displacements about 5~15m. They are all normal faults, and the upper breakpoints of the faults cut the Pleistocene strata.
The result of the exploration of Cixian-Daming Fault is not consistent with the buried depth 1 200m proposed by XU Hua-ming. It is proved that the activity of the fault is also consistent with the overall activity of the Cixian-Daming Fault, which is an active fault since late Pleistocene.
The Dachengdong Fault and Cangxi Fault offset the middle Pleistocene strata. Although the late Pleistocene active faults are generally defined as active faults in the practice of active tectonics research in China, strong earthquakes in eastern China have shorter recurrence period, and earthquakes of magnitude 6 or so may also occur in some middle Pleistocene active faults.
During the compilation of GB18306-2015 “Seismic ground motion parameter zonation map of China”, there were no late Pleistocene active faults in the M6~6.5 potential source areas in eastern China. Therefore, we believe that the Dachengdong and Cangxi faults still have the ability to generate earthquake of magnitude 6 or so, and the faults have some similarities with the seismogenic structures of Xingtai earthquake swarm. Under the action of the latest tectonic stress field, the “deep faults” tearing ruptured successively and expanded upwards, resulting in stress migration and loading between two neighbouring en-echolon concealed faults, so, the Dachengdong and Cangxi faults are the product of this three-dimensional rupture process. The Dachengdong Fault is a “newly-generated” fault resulting from the tearing rupturing and upward expanding of the pre-existing concealed “deept faults” in the middle and lower curst. 相似文献
The result of the exploration of Cixian-Daming Fault is not consistent with the buried depth 1 200m proposed by XU Hua-ming. It is proved that the activity of the fault is also consistent with the overall activity of the Cixian-Daming Fault, which is an active fault since late Pleistocene.
The Dachengdong Fault and Cangxi Fault offset the middle Pleistocene strata. Although the late Pleistocene active faults are generally defined as active faults in the practice of active tectonics research in China, strong earthquakes in eastern China have shorter recurrence period, and earthquakes of magnitude 6 or so may also occur in some middle Pleistocene active faults.
During the compilation of GB18306-2015 “Seismic ground motion parameter zonation map of China”, there were no late Pleistocene active faults in the M6~6.5 potential source areas in eastern China. Therefore, we believe that the Dachengdong and Cangxi faults still have the ability to generate earthquake of magnitude 6 or so, and the faults have some similarities with the seismogenic structures of Xingtai earthquake swarm. Under the action of the latest tectonic stress field, the “deep faults” tearing ruptured successively and expanded upwards, resulting in stress migration and loading between two neighbouring en-echolon concealed faults, so, the Dachengdong and Cangxi faults are the product of this three-dimensional rupture process. The Dachengdong Fault is a “newly-generated” fault resulting from the tearing rupturing and upward expanding of the pre-existing concealed “deept faults” in the middle and lower curst. 相似文献