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滇西北地区断层破碎带宽度与断层错距的统计关系 总被引:1,自引:0,他引:1
本文以非粘土断层泥带宽度与断层错距在断层(带)发育中期线性相关的实验结果为依据,对滇西北地区断层破碎带宽度(W)与断层错距(D)的关系作了统计分析,目的在于建立一种从断层破碎带几何特征反演断层背景位移的新方法。通过对该区中等发育程度的33条断层48组样本的统计,得到相关性较好的D=18.5W的经验关系式,同时还就这一关系式的适用范围及影响因素进行了分析讨论。应用D—W关系,确定了直线型的剑川断裂中北段的背景位移分布,并提出断层的背景位移分布可作为断层分段的一个重要指标。 相似文献
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根据作者等人野外实地考察,1920年海原8(1/2)级大地震的地层断层全长225km,共由6条几何参数不同的次级断层呈有规律的斜列状组合而成.每一条次级断层都可分为形变性质不同的三段,其中中段以水平走滑性质为主;两端以垂直形变为主,表现为逆断层和正断层性质.垂直和水平位移的测量数据也表明,每一条次级断层的中段水平位移最大,向两端逐渐减小,以至消失,而垂直位移正好相反,中段小,两端大.整个断层的地震位移显示出多个峰值的形变特征.这种形变特征表明,海原大地震的6条次级断层都是各个相对独立的水平位移间断面(即位错面),每个位错面,都可以代表一次独立的次级地震破裂事件.作者等据此认为,巨大的8(1/2)级海原大地震可能是由6次相对独立的次级地震事件接续发生的结果. 相似文献
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根据作者等人野外实地考察,1920年海原8(1/2)级大地震的地层断层全长225km,共由6条几何参数不同的次级断层呈有规律的斜列状组合而成.每一条次级断层都可分为形变性质不同的三段,其中中段以水平走滑性质为主;两端以垂直形变为主,表现为逆断层和正断层性质.垂直和水平位移的测量数据也表明,每一条次级断层的中段水平位移最大,向两端逐渐减小,以至消失,而垂直位移正好相反,中段小,两端大.整个断层的地震位移显示出多个峰值的形变特征.这种形变特征表明,海原大地震的6条次级断层都是各个相对独立的水平位移间断面(即位错面),每个位错面,都可以代表一次独立的次级地震破裂事件.作者等据此认为,巨大的8(1/2)级海原大地震可能是由6次相对独立的次级地震事件接续发生的结果. 相似文献
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一言以蔽之 ,该书是关于野岛地震断层2 0 0多页的全部记录集 ,是距兵库县南部地震整整 5年来著者们研究的重大成果。所谓全记录集 ,它的内容非常独特。开头的 66页收录了从飞机和直升机上拍摄的漂亮的照片 ,以及用彩卷拍摄的每个露头断层全貌的照片 1 3 2张 ,并且还有地震后最早赶到现场的著者们拍摄的崭新的贵重影像。后面的 2 9页登载了 1 / 40 0 0 (底图比例尺为1 / 2 50 0 )比例尺的地形图 ,图上标有地震断层、龟裂、斜坡破坏、滑坡等位置的全区图集。另外还增加了包括 1 66个观察点在内的断层、龟裂的地表形状 ,走向、倾斜、位移量、位… 相似文献
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逆断层地震近场地震动影响场和地表形变模拟 总被引:4,自引:0,他引:4
本文设计了一个MW7.0级地震的简单的逆断层有限移动源破裂模型,计算了断层周围64个观测点的加速度、速度和位移时程及峰值,简单讨论了近场地震动峰值、断层附近地表永久位移(或地表形变)的分布特点,并讨论了永久位移和地面运动速度大脉冲的关系。重点研究了断层附近三分量的永久位移(或地表形变)大小、方向和地震动作用特点。 相似文献
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1973年2月在鲜水河断裂带炉霍段发生了M7.6地震破裂.自那以来,先后在炉霍县虾拉沱布设了若干横跨该地震断层(1973年破裂带)的地壳形变观测系统,包括断层近场的短基线、短水准、蠕变仪、人工构筑物等,以及断层近-远场的GPS观测站.利用这些观测系统的长期观测资料,本文分析了鲜水河断裂带炉霍段的震后滑动/变形及其时、空变化特征,并建立起解释这些特征的动力学模式.研究表明:(1)1973年地震后的头5年,地震断层在虾拉沱场地表现为开放性质,近场的断层震后滑动以无震左旋蠕滑为主,速率达到10.27 mm/a,且伴有微量的拉张性蠕动作用;1979年以来,左旋蠕滑速率由5.3 mm/a逐渐减小到2.27 mm/a,减小的过程呈对数函数型,反映此阶段断层面已逐渐重新耦合、正朝闭锁的方向发展,并伴有部分应变积累.(2)1999年以来,地震断层两侧远场的相对左旋位移/变形速率为10 mm/a,远大于同时期断层近场(跨距40~144 m)的左旋蠕滑速率0.66~2.52 mm/a;远-近场位移/形变速率的显著变化发生在地震断层两侧各宽约30 km的范围,显示出这是与大地震应力应变积累-释放相关的断裂带宽度.(3)结合动力学背景与深部构造信息,本文对这里断层的震后位移/变形及其时、空变化的机理进行初步解释,要点是:震后约5年之后,由于逐渐增大的断层滑动/摩擦阻抗,上地壳脆性层中的断层面由震后初期的开放性质逐渐转向重新耦合、并朝闭锁的方向发展,但其两侧地块深部持续的延性相对运动拖拽着浅部脆性层发生相应的弹性位移/变形.(4)可估计再经历15~25年,研究断裂段将完全"闭锁",即进入积累下一次大地震应力应变的震间闭锁阶段. 相似文献
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1954年山丹地震遗留至今的破裂带主要有 2条 :包代河至黑山头为主破裂带 ,长约 16km ;独峰顶至坡拉麻顶为次级破裂带 ,断续分布长约 10km .2条破裂带走向均为NW ,近于平行 ,二者相距约 6km ,分别由地震断层、崩塌和地裂缝等构成 .(1)地震断层 :分布于包代河口至大峡河以东海拔 2 0 0 0m左右的山麓地带 ,长度大于 2km ,走向N50°W .地表破裂与先存断层重合 .在剖面上可见花岗岩与白垩系砂砾岩呈断层接触 .该断层水平和垂直位移均很显著 ,最大垂直位移 1.2m ,多数小于 1m ,在地貌上显示为反坡向陡坎 ;最大水平位移 3.5~ 4m ,… 相似文献
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小江断裂带西支断裂南段新活动初探 总被引:11,自引:0,他引:11
本文根据实地调查,分析了小江西支断裂南段两条分支断裂的展布特征及其活动性。用冲沟长度、错动量及平均侵蚀速率,估算了断裂的水平滑动速率。指出南段分支断裂作多重右阶斜列展布,现今活动以左旋走滑为主,兼有倾向运动分量,全新世以来平均水平滑动速率为1.66mm/a。 相似文献
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DISCUSSION ON THE SEISMOGENIC STRUCTURE OF ZHAN-JIANG BAY AREA FROM THE VIEW OF DEEP FAULT SYSTEM INTERPRETED BASED ON THE GRAVITY DATA 下载免费PDF全文
The neotectonics in Zhanjiang Bay area is almost the inferred faults and there are not any active faults seen on the ground surface. So it is difficult for research on the seismogenic structure. This paper analyzes and interpretes the gravity data that can reflect the feature of deep faults and then discusses the seismogenic structure of Zhanjiang Bay area in combination with its geology and earthquake activity. There is a huge NEE-trending high gravity gradient belt lying in the coastal region among Guangdong, Guangxi, and Hainan, and Zhanjiang Bay is located in this gravity gradient belt. We analyzed and interpreted more than eighty images obtained with many different methods one by one, then, got the result that Zhanjiang Bay area is embraced by two giant fault belts trending in the NEE and NW direction respectively, and its interior is crossed over by the NE-trending fault belt. These three fault belts are well shown in the gravity images, especially the NEE-trending fault belt and NW one. The gravity isolines and gradient belts or the thick black stripes of the NEE-and NW-trending fault belts are displayed apparently. Also, these gravity structures are good in continuity, extend vastly and cut deeply. What is more, the NEE-trending fault belt plays a leading and region-controlling part. It shows good continuity, and cuts off the NW-and NE-trending faults frequently and intensively. The NW-trending fault belt also is good in continuity and cuts the NEE-and NE-trending faults relatively frequently and strongly, but it is restricted by the NEE-trending one. Last, the continuity of the NE-trending fault is worse and the strength cutting off NE-and NW-trending faults is significantly weak, just in some segments and in the shallow positions. According to the characteristics above and combined with the analyses of geological structure and earthquake activity, the conclusion can be drawn that the NEE-trending fault is the controlling structure and the main seismogenic structure in Zhanjiang Bay area, and the NW-trending fault is the second one. They conjugate and act together. Therefore, Zhanjiang Bay has the tectonic condition for generating MS=6.5 earthquakes. 相似文献
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安宁河断裂带是中国西南地区一条重要的地震活动断层, 地方志记载公元1536年曾发生过震级大于7级的破坏性地震. 详细的断裂地貌航片解译和野外调查表明, 安宁河断裂带除具有主要的左旋走滑断层活动外,还兼有重要的逆冲运动分量. 根据冲沟和阶地面的位错量及其热释光测年结果估计,该断裂带晚更新世以来平均左旋走滑速率为3~7 mm/a. 根据滑移方向与断层走向的关系,推测跨安宁河断裂带东西向由于逆冲断层运动造成的挤压缩短速率约为1.7~4.0 mm/a; 简单分解鲜水河断裂带上的滑动速率,估计分配在大凉山断裂带上的滑动速率与安宁河断裂带上的大致相当,约为3~7 mm/a. 此外,根据野外调查结果,并结合最近青藏高原构造动力学研究的新认识, 建立了安宁河断裂带的动力学模型,认为安宁河断裂带是一条逆冲走滑断裂带. 其下盘(西盘)主动向南东方向下插,造成了上盘(东盘)向北西方向的上冲运动. 相似文献
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利用浅地层剖面仪对郯庐断裂带莱州湾段进行了活断层探测,发现郯庐断裂带主干断裂在第四纪晚期以来具有明显的活动,继承了晚第三纪以来的主要构造活动特点,仍是这一区域的主导性构造. 西支KL3断裂由多条高角度正断裂组成,最新活动时代为晚更新世晚期至全新世早期,受到一系列错断晚更新世晚期沉积的北东或近东西向断裂的切割;东支龙口断裂由两段右阶斜列的次级断层组成,沿断裂带不但有明显的晚第四纪断错活动,而且还发育北北东向晚第四纪生长褶皱,表现出明显的晚更新世晚期至全新世活动特征. 在山东陆地区也发现了与龙口断裂相对应的安丘——莒县断裂,安丘段由一系列右阶斜列的次级断层组成. 从安丘向北至莱州湾凹陷,郯庐断裂带东支活断层构成了一条右旋单剪变形带,每一个次级活断层段相当于带内理论上次级压剪面,在第四纪晚期以来仍以右旋走滑活动为主要特征. 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
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