FAULT ACTIVITY OF THE SOUTHWESTERN SEGMENT OF THE EASTERN BRANCH OF XINYI-LIANJIANG FAULT ZONE IN GUANGDONG PROVINCE          下载免费PDF全文

ZHANG Long-sheng  ZHOU Ben-gang  JI Feng-ju  YANG Xiao-ping  AN Yan-fen 《地震地质》2016,38(2):316-328

The NE-trending Xinyi-Lianjiang fault zone is a tectonic belt, located in the interior of the Yunkai uplift in the west of Guangdong Province, clamping the Lianjiang synclinorium and consisting of the eastern branch and the western branch. The southwestern segment of the eastern branch of Xinyi-Lianjiang fault zone, about 34km long, extends from the north of Guanqiao, through Lianjiang, to the north of Hengshan. However, it is still unclear about whether the segment extends to Jiuzhoujiang alluvial plain or not, which is in the southwest of Hengshan. If it does, what is about its fault activity? According to ‘Catalogue of the Modern Earthquakes of China’, two moderately strong earthquakes with magnitude 6.0 and 6.5 struck the Lianjiang region in 1605 AD. So it is necessary to acquire the knowledge about the activity of the segment fault, which is probably the corresponding seismogenic structure of the two destructive earthquakes. And the study on the fault activity of the segment can boost the research on seismotectonics of moderately strong earthquakes in Southeast China. In order to obtain the understanding of the existence of the buried fault of the southwestern segment, shallow seismic exploration profiles and composite borehole sections have been conducted. The results indicate its existence. Two shallow seismic exploration profiles show that buried depth of the upper breakpoints and vertical throw of the buried fault are 60m and 4~7m(L5-1 and L5-2 segment, the Hengshan section), 85m and 5~8m(L5-3 segment), 73m and 3~5m(Tiantouzai section), respectively and all of them suggest the buried fault has offset the base of the Quaternary strata. Two composite borehole sections reveal that the depth of the upper breakpoints and vertical throws of the buried segment are about 66m and 7.5m(Hengshan section) and 75m and 5m(Tiantouzai section), respectively. The drilling geological section in Hengshan reveals that the width of the fault could be up to 27m. Chronology data of Quaternary strata in the two drilling sections, obtained by means of electron spin resonance(ESR), suggest that the latest activity age of the buried fault of the southwestern segment is from late of early Pleistocene(Tiantouzai section) to early stage of middle Pleistocene(Hengshan section). Slip rates, obtained by Hengshan section and Tiantouzai section, are 0.1mm/a and 0.013mm/a, respectively. As shown by the fault profile located in a bedrock exposed region in Shajing, there are at least two stages of fault gouge and near-horizontal striation on the fault surface, indicating that the latest activity of the southwestern segment is characterized by strike-slip movement. Chronology data suggest that the age of the gouge formed in the later stage is(348±49) ka.  相似文献   

TRANSVERSE STRUCTURES FEATURES OF DIFFERENT DEPTHS DERIVED FROM BOUGUER GRAVITY ANOMALIES IN THE SOUTHERN SEGMENT OF TAN-LU FAULT ZONE          下载免费PDF全文

WANG Xin  ZHANG Jing-fa  JIANG Wen-liang  JIANG Hong-bo  TIAN Tian  GAO Min  FU Ping-jie 《地震地质》2016,38(2):370-385

To research the faults distribution and deep structures in the southern segment of Tan-Lu fault zone(TLFZ) and its adjacent area, this paper collects the Bouguer gravity data and makes separation by the multi-scale wavelet analysis method to analyze the crustal transverse structure of different depths. Meanwhile Moho interface is inversed by Parker variable density model. Research indicates that the southern segment of TLFZ behaves as a NNE-directed large-scale regional field gravity gradient zone, which separates the west North China-Dabie orogen block and the east Yangtze block, cutting the whole crust and lithosphere mantle. There are quite differences of density structures and tectonic features between both sides of this gradient belt. The sedimentary and upper crustal density structure is complex. The two east branches of TLFZ behave as linear gravity anomalous belt throughout the region, whereas the two west branches of TLFZ continue to extend after truncating the EW-trending gravity anomaly body. The lower crustal density structure is relatively simple. TLFZ behaves as a broad and gentle low abnormal belt, which reflects the Cretaceous-Paleogene extension environment caused graben structure. The two west branches of TLFZ, running through Hefei city, extend southward along the west margin of Feidong depression and pinch out in Shucheng area due to the high density trap occlusions in the south of Shucheng. The Feizhong Fault, Liu'an-Hefei Fault, and Feixi-Hanbaidu Fault intersect the two west branch faults of TLFZ without extending to the east. Recent epicenters are mainly located in conversion zones between the high-density and the low-density anomaly, especially in TLFZ and the junction of the faults, where earthquakes frequently occurred in the upper and middle crust. As strong earthquakes rarely occur in the southern segment of TLFZ, considering its deep feature of abrupt change of the Moho and intersections with many EW-trending faults, the hazard of strong earthquake cannot be ignored.  相似文献   

CHANGES IN FAULT MOVEMENT PROPERTY AND GENETIC MECHANISM ON THE WESTERN SEGMENT OF THE XIANGSHAN-TIANJINGSHAN FAULT ZONE          下载免费PDF全文

LI Xin-nan  LI Chuan-you  ZHANG Pei-zhen  WANG Xu-guang  ZHANG Long-sheng 《地震地质》2016,38(3):732-746

The Xiangshan-Tianjingshan fault zone is an important part of the arc tectonic zone in northeastern Tibet, whose eastern segment is characterized by primarily left-lateral slip along with thrust component. In contrast, the fault movement property on the western segment of the Xiangshan-Tianjingshan fault zone is more complicated. According to the offset geomorphic features and cross sections revealed by the trenches and outcrops, the western segment is mainly a left-lateral strike-slip fault with normal component, and only accompanied with reverse component at specific positions. To determine the genetic mechanism of fault movement property on the western segment, we obtained three main factors based on the integrated analysis of fault geometry:(1)Step-overs:the left-stepping parallel faults in a sinistral shear zone create extensional step-overs and control the nearby and internal fault movement property; (2)terminal structures:they are conductive to stop rupture propagation and produce compressive deformation at the end of the fault trace; and(3)double bends:strike-slip faults have trace that bends such that slip between two adjacent blocks creates a compressive stress and thrust fault. Additionally, the Tianjingshan sub-block moves to SEE and creates an extensional stress at the end of the sub-block associated with normal faults. It shows that the Xiangshan-Tianjingshan fault zone has a complex evolution history, which is divided into two distinctive periods and characterized by laterally westward propagating.  相似文献   

青藏高原班公湖-怒江缝合带丁青-碧土段大地构造演化   总被引：5，自引：2，他引：3  

蒋光武  谢尧武  白珍平  西诺朗杰  强巴扎西  彭兴阶 《地质通报》2009,28(9):1259-1266

藏东班公湖-怒江缝合带丁青-碧土段位于该缝合带由东西向转向南北向的转折部位,夹持于冈瓦纳大陆冈底斯-察隅陆块与泛华夏扬子大陆昌都-思茅陆块之间,经历过强烈伸展、挤压、碰撞、急剧沉降和隆升,是地质构造极其复杂的造山带。其沉积构造环境复杂多样,与该缝合带发展演化有关的岩浆活动极其强烈、频繁,并发育有高压变质带。丁青-碧土-怒江洋盆经历了较为完整的威尔逊旋回,包括裂谷-初始洋盆阶段、洋盆扩张阶段、俯冲消减阶段、封闭碰撞阶段的发展和演化。  相似文献   

龙门山南段飞来峰构造变形及形成演化   总被引：1，自引：0，他引：1  

宋春彦  何利  刘顺 《华南地质与矿产》2009,(1):51-57

龙门山前山构造带中分布着大量的飞来峰。为了解其构造演化过程,主要通过分析研究龙门山南段白石-苟家飞来峰和金台山飞来峰内部及下覆地层的构造变形特征,确定出其至少经历了5个构造变形序列,并结合前人资料讨论龙门山南段飞来峰的形成和演化。  相似文献   

历史大地震破裂区地震危险性的地震活动性定量分析—以南北地震带中北段为例     

龙锋  蒋长胜  冯建刚  唐兰兰 《中国地震研究》2013,27(3):331-343

尽管地震空区理论在中长期地震预测中起着重要的作用,但大地震复发在时间上的丛集或非线性行为使得在中长期地震预测研究中依然需要同时考虑非地震空区的、历史地震破裂区的潜在大地震危险性。为了探索能基于观测资料分析的、鉴别历史地震破裂区（包括历史、史前地震破裂的地震空区）大地震复发危险性的技术方法,我们在南北地震带中北段挑选出8个具有不同离逝时间的历史大地震破裂区,分析这些破裂区现代地震活动性的量化特征,以初步探索判定潜在大地震危险性紧迫程度的地震活动性方法。结果主要显示,反映地震序列衰减状态的p值和反映地震活动率的a值与这些历史破裂区最晚大地震的离逝时间有较好的对应关系,但也有部分破裂区可能由于复杂的断层结构与运动性质,对应关系并不明确;反映构造应力积累状况的b值则难于反映离逝时间演化阶段的信息。b值的时间扫描结果显示,大部分历史破裂区的b值随时间演化平稳,但1879年甘肃武都8级地震破裂区的b值则表现为明显的涨落,并存在持续20年的降低趋势。对比分析认为,1933年四川茂县7.5级、1976年四川松潘-平武两次7.2级地震破裂区目前仍处于序列衰减期,不具备再次发生7级以上地震的背景;公元842年迭部7级地震破裂区北缘低b值的玛曲段比迭部段更具危险性;1879年武都8级地震破裂区的b值持续降低也可能反映该区处于新的一轮孕震期。  相似文献   

龙门山断裂带南段应力状态与强震危险性研究   总被引：17，自引：5，他引：12       下载免费PDF全文

易桂喜  闻学泽  辛华  乔慧珍  王思维  宫悦 《地球物理学报》2013,56(4):1112-1120

龙门山断裂带可分为南段、中段和北段,2008年汶川M8.0级地震发生在该断裂带中-北段. 龙门山断裂带南段是否存在发生强震的危险性倍受关注. 利用1977-2012年四川区域地震台网资料,获得了龙门山断裂带南段的地震活动性参数b值图像以及汶川地震前、后b值的差值Δb图像. 同时,根据宽频带数字地震波形资料,计算了2007年以来南段及附近区域M_L≥3.8级地震的视应力. 结果表明,2008年汶川地震后,龙门山断裂带南段天全-芦山、泸定和宝兴北部等区域应力增强,而靠近汶川余震区南端的大邑地区应力水平降低. 天全至宝兴段应力水平相对较高,具有发生中-强地震的条件. 鲜水河断裂带康定以南段应力水平低,短期内发生强震的可能性较小.  相似文献   

基于Mindlin解的压力型锚杆锚固段的受力分析          下载免费PDF全文

贺建清  胡成兵  张建超 《水文地质工程地质》2012,39(1):47-52

假设锚杆为与周围介质相同的材料,视锚杆作用的岩土体为弹性半空间位移体;基于Mindlin位移解,求出集中力作用下周围岩土体沿锚固体的轴向位移;根据压力型锚杆锚固段的受力状态,计算锚固体在轴向荷载作用下压缩变形,利用锚固体与周围岩土体变形协调假定,推导出锚固段轴向应力和剪应力分布的理论解。经过与已有现场试验实测数据对比分析,验证了理论解的可行性,并在此基础上讨论了相关岩土参数对锚固段轴向应力和剪应力的影响。锚杆现场试验和理论分析结果表明:压力型锚杆的锚固段所受轴向应力和剪应力与锚固力成正比;压力型锚杆的锚固段所受剪应力的分布形式受周围岩土体弹模、泊松比以及锚固体与周围岩土体界面的内摩擦角等因素的影响。其中周围岩土体的弹模影响最大。  相似文献   

安徽沿江地区晚石炭世黄龙组白云岩地球化学特征及其成因研究          下载免费PDF全文

赵大千  李双应  王冰  嵇在飞  芦艳琳  孟祥金  吕庆田 《地质科学》2012,(3):851-866

安徽沿江地区晚石炭世黄龙组白云岩广泛发育,主要为晶粒白云岩,其次是角砾白云岩和残余颗粒白云岩。地球化学分析表明,安徽沿江地区黄龙组白云岩中Fe、Mn、Sr、Na含量分别为:2 567×10^-6(1 600×10^-6～4 400×10^-6)、353×10^-6(166×10^-6～742×10^-6)、109.7×10^-6(69.0×10^-6～176.5×10^-6)、288×10^-6(100×10^-6～700×10^-6),稀土元素总量为7.29×10^-6(2.56×10^-6～20.82×10^-6),ΣLREE/ΣHREE比值平均为3.07(1.16～10.17),经海水标准化后,显示LREE富集,HREE相对亏损,δCe平均为4.53(2.82～7.78),正异常显著,δEu平均为1.85(0.94～2.92),配分模式曲线显示白云岩化流体来自海水。白云岩中可见蒸发岩类或蒸发构造。综合分析认为该地区白云岩主要为准同生成因,部分为埋藏成岩成因,其中角砾白云岩为准同生成因,怀宁地区白云岩δEu平均为2.38(1.91～2.92),正异常显著,表明后期受到热液流体影响。  相似文献   

库车坳陷中部构造分层差异变形特征和构造演化   总被引：1，自引：1，他引：0  

谢会文  李勇  漆家福  李青  陈元勇  玛丽克  许安明 《现代地质》2012,26(4):682-690

基于地表露头调查、地震资料解释、钻井及与盐相关的构造样式分析,对库车坳陷中部构造变形特征进行研究。结果表明:库车坳陷中部具有南北分带、东西分段、垂向分层的变形特征。以库姆格列木群膏盐岩为界可以分为盐上构造层、盐构造层、盐下构造层及基底构造层4层结构。该区域主要发育收缩构造样式及盐构造样式,盐上构造层、盐构造层及盐下构造层的构造样式及分布具有明显差异。盐上层主要发育逆冲断层及褶皱,盐岩层则以盐流动构造样式为主,盐下层则发育逆冲叠瓦断层等大规模推覆构造。研究区具有明显的分段变形特征,可划分为博孜—却勒构造段、大北—西秋构造段、克深—西秋构造段、克拉3—东秋构造段,其差异性主要表现为地表线性褶皱带分布、盐构造样式、盐下构造变形的差异。区域构造演化剖面研究表明库车坳陷主要经历了中生代伸展坳陷盆地(三叠纪—白垩纪)、新生代早期"挠曲"盆地(古近纪—中新世)及新生代晚期前陆盆地(上新世—第四纪)的演化过程。现今构造主要形成于库车组沉积的中晚期。  相似文献