共查询到20条相似文献,搜索用时 125 毫秒
1.
北西向张家口-蓬莱断裂带由近20条北西至北西西向断裂组成,是一条对新生代区域地质构造发育起到重要控制作用的地壳构造带。断裂带新生代活动由中部向西北和东南部发展,总体表现左旋走滑性质。断裂带有山西断陷盆地带等几条北东向活动构造带与之交汇,形成北西和北东向两组断裂相互交切的构造组合,出现5个复杂的构造交接段。6级以上强震和大多数中小地震群集于这些地段,其中北西和北东向断裂都可能发生地震,显示共轭破裂错动特征,但北东向断裂发生的地震强度较大。张北-尚义6.2级地震发生于断裂带与山西断陷盆地带交接段的西缘,是断裂带向西北扩展的结果 相似文献
2.
龙门山断裂带北段活动特征的遥感地质解译研究 总被引:2,自引:0,他引:2
文中通过龙门山断裂北段卫星遥感影像的解译分析,对该区活动断裂的分布与发育情况进行了研究.文章选取ETM光学影像和遥感1号雷达影像为主要数据源,结合研究区已有研究成果,分析了遥感影像上地质地貌特征,建立了研究区的解译标志,对龙门山断裂带北段主要断裂(平武-青川断裂、南坝-林庵寺断裂、江油-广元断裂)分布特征与活动性进行了深入的遥感解译.研究结果表明,平武-青川断裂对不同规模的水系位错的影响较大,且广元地区历史地震主要分布在该断裂带上,因此平武-青川断裂活动性最强,对该区地震的发生起着重要的控制作用. 相似文献
3.
热水—日月山断裂带在遥感影像上具有明显的线性构造特征,通过解译认为该断裂带由6条不连续的断裂段右阶羽列组成,活动特征很明显,造成一系列水系断错,最大水平位错940 m,并沿断裂带形成一系列小拉分盆地,认为该断裂带具有较强的右旋走滑特征。其中牧场部—大崖根段北西西向沿湟水河河谷发育,除其本身具有发生强震的构造能力外,其延伸是否与西宁市区中的沿湟水河谷地附近的地表断层相连,对西宁盆地的构造活动形式及地震构造特征有十分重要的意义。历史地震表明曾在热水煤矿与大通山构造复合部位于1927年连续发生多次M4.5~5.5级中强地震。 相似文献
4.
5.
丽江地区活动性构造发育,地震发生频繁。以遥感影像线环结构理论论述了该区主要活动断裂和活动环块的遥感影像特征和地质地貌特征,并分析活动构造与场地稳定性的关系,进而划分出该区内易发震地区与相对稳定的地区。 相似文献
6.
吉林省松原地区1119年6 3/4级地震的发震构造条件 总被引:2,自引:0,他引:2
1999年6 3/4级地震是东北地区震级在的地震,目前对其发震构造背景缺乏深入的研究。本文从深部构造背景,浅层构造条件和深浅部构造关系等方面,对1119年地震的发震构造背景作了剖析。研究认为,本次地震的宏观震中位于扶余-前郭一带,地质构造上,该区处于松辽盆地中央凹陷和东南隆起的交接部位;深部构造背景上,该区是莫霍面起伏的拐点,存在北东向基底断鲜明和弱西向深部断裂,前者规模较大,晚新生代有弱活动,是 相似文献
7.
西藏地区地壳活动强烈,活动断层发育,存在很大的地震灾害风险,因此查清活动断层的分布是一项重要工作。遥感解译是查明活动断层最有效的手段,其核心技术是正确把握活动断层的典型遥感影像特征。文中结合1︰100万全国地震构造图(西藏区)编制工作,利用高分辨率卫星遥感影像对西藏地区改则幅(I45)全新世活动断层的典型遥感影像特征进行了研究,确定了区内全新世活动断裂玛尔盖茶卡断裂、日干配错断裂、依布茶卡地堑、青蛙湖断裂、东查断裂、其香错断裂中段的空间展布。结合前人的研究成果及区域对比分析,讨论了区内全新世断裂的最新活动时代、活动性质和活动强度,以及区内活动断裂的整体构造运动特征和发震能力。研究区北部的玛尔盖茶卡断裂和南部的日干配错断裂、其香错断裂为较大规模的NEE向左旋走滑断裂,具备发生约7.5级地震的能力。中部还发育了NEE向依布茶卡地堑、青蛙湖断裂和NW向东查断裂这3条规模相对较小的全新世断层,具备发生约7级地震的能力。上述断裂反映了该区受到SN向挤压,形成“V”字形共轭系统,总体运动特征表现为块体向E挤出的动力环境。 相似文献
8.
9.
青海拉脊山断裂带新活动特征的初步研究 总被引:10,自引:0,他引:10
拉脊山断裂带由拉脊山北缘断裂和拉脊山南缘断裂两条向NE凸出的弧形断裂所组成,分别长约230km和220km。它们是介于NNW向的热水一日月山右旋走滑断裂带和NWW向的西秦岭北缘左旋走滑断裂带之间的一个大型挤压构造区和构造转换带,也是分隔拉脊山南北两侧的西宁一民和盆地和循化一化隆盆地的重要边界断裂。沿断裂带的追踪考察,发现了其新活动的部分地质地貌证据。其最新活动时代为晚更新世晚期(仅局部为全新世早期),性质以挤压逆冲为主稍具左旋特征。该断裂的新活动可能导致了该区20余次5级左右中等地震的发生。可以说,拉脊山地区既是反映构造活动,又是反映地震活动的地震构造窗。 相似文献
10.
11.
12.
1936年广西灵山M6? 地震是华南沿海地震带内陆地区有地震记载以来发生的最大地震,由于当时仪器记录缺乏、时代相隔较长且未进行详细的现场调查,对该地震的基本参数尚存争议。本文在概述该地震地表破裂带基本特征的基础上,利用地震地表破裂带长度和最大同震位移等数据重新讨论了该地震的基本参数和发震构造。研究结果表明1936年灵山M6? 地震的宏观震中位于灵山断裂北段与友僚—蕉根坪断裂交会处一带,震级为M6.8左右,震中烈度达Ⅸ度强,罗阳山西北麓的灵山断裂为该地震的发震构造。 相似文献
13.
The 2014 Jinggu M6.6 earthquake attacked the Jinggu area where few historical earthquakes had occurred and little study has been conducted on active tectonics. The lack of detailed field investigation on active faults and seismicity restricts the assessment of seismic risk of this area and leads to divergent view points with respect to the seismotectonics of this earthquake, so relevant research needs to be strengthened urgently. In particular, some studies suggest that this earthquake triggered the activity of the NE-trending faults which have not yet been studied. By the approaches of remote sensing image interpretation, structural geomorphology investigation and trench excavation, we studied the late Quaternary activity of the faults in the epicenter area, which are the eastern margin fault of Yongping Basin and the Yixiang-Zhaojiacun Fault, and drew the conclusions as follows:
(1)The eastern margin fault of Yongping Basin originates around the Naguai village in the southeastern margin of Yongping Basin,extending northward across the Qiandong, Tianfang, and ending in the north of Tiantou. The fault is about 43km long, striking near SN. The linear characteristic of the fault is obvious in remote sensing images. Structural geomorphological phenomena, such as fault troughs, linear ridges and gully dislocations, have developed along the faults. There are several dextral-dislocated gullies near Naguai village, with displacements of 300m, 220m, 146m, 120m and 73m, respectively, indicating that the fault is a dextral strike-slip fault with long-term activity. In order to further study the activity of the fault, a trench was excavated in the fault trough, the Naguai trench. The trench reveals many faults, and the youngest strata offseted by the faults are Holocene, with 14C ages of(1 197±51)a and(1 900±35)a, respectively. All those suggest that it is a Holocene active fault.
(2)The Yixiang-Zhaojiacun Fault starts at the southeast of the Jinggu Basin, passes through Xiangyan, Yixiang, Chahe, and terminates at the Zhaojiacun. The total length of the fault is about 60km, and is a large-scale NE-trending fault in the Wuliangshan fault zone. Four gullies are synchronously sinistrally dislocated at Yixiang village, with the displacements of 340m, 260m, 240m and 240m, indicating that the fault is a long-term active sinistral strike-slip fault. A trench was excavated in a fault trough in Yixiang village. The trench reveals a small sag pond and a fault. The fault offsets several strata with clear dislocation and linear characteristic. The thickness of strata between the two walls of fault does not match, and the gravels are oriented along fault plane. The offset strata have the 14C age of(2 296±56)a, (3 009±51)a, and(4 924±45)a, respectively, and another two strata have the OSL age of(1.8±0.1)ka, (8.6±0.5)ka respectively, by which we constrained the latest paleoearthquake between(1.8±0.1)ka(OSL-Y01)and(378±48)a BP(CY-07). This again provides further evidence that the fault is a Holocene fault with long-term activity.
(3)Based on the distribution of aftershocks and the predecessor research results, the 2014 Jinggu M6.6 earthquake and the M5.8, M5.9 strong aftershocks are regarded as being caused by the eastern margin fault of Yongping Basin, which is part of the Wuliangshan fault zone. The seismogenic mechanism is that the stress has been locked, concentrated and accumulated to give rise to the quakes in the wedge-shaped area near the intersection of the SN and NE striking faults, which is similar to the seismogenic mechanism in the southwest of Yunnan Province. 相似文献
14.
15.
根据邢台7-2 级和6-8 级地震震中区的浅层和超浅层地震勘探结果,查明了震中区浅部铲形断裂的性质及活动年代,认为新河断裂(F1) 自晚更新世以来已不再活动,它不是发震断裂。另外,结合该区深地震反射剖面和深地震测深剖面结果,讨论了震中区的深浅部构造形态及它们的相互关系,从而确定了发震断裂应为震源之下的高倾角超壳断裂①。邢台地震的发生是由于地幔岩浆的上侵作用产生附加应力场,并与区域构造应力场共同作用使该断裂重新活动,引发了邢台地震,并引起浅部断层及地表物质的运动 相似文献
16.
In order to provide a basis for the earthquake resistance protection zoning of Anshan City, westudied the activity of faults. In the study, the synthetic geophysical prospecting techniqueswere used. These techniques include the shallow artificial earthquake method, electric method,geologic radar method, etc., with shallow artificial earthquake sounding as the main means.In the meantime, the data of geophysical prospecting and borehole record of this city werecollected and the methods of field investigation and sample age dating were also used incombination. The results show that there are 5 hidden or semi-hidden faults in Anshon City.Among these faults, Dashitou-Songsantai fault, Ningyuantun fault and Dayangqi fault trendNW, the middle Pleistotene Tanggangzi fault trends NE, while the early Pleistocene or Pre-Quaternary Ertaizi fault trend NW. According to the definition of active faults, none of thesefaults is active. This paper also discussed the cause for the formation of seriously damagedareas in Ans 相似文献
17.
Five mobile digital seismic stations were set up by the Earthquake Administration of Yunnan Province near the epicenter of the main shock after the Ning’er M6.4 earthquake on June 3, 2007. In this paper, the aftershock sequence of the Ning’er M6.4 earthquake is relocated by using the double difference earthquake location method. The data is from the 5 mobile digital seismic stations and the permanent Simao seismic station. The results show that the length of the aftershock sequence is 40km and the width is 30km, concentrated obviously at the lateral displacement area between the Pu’er fault and the NNE-trending faults, with the majority occurring on the Pu’er fault around the main shock. The depths of aftershocks are from 2km to 12km, and the predominant distribution is in the depth of 8~10km. The mean depth is 7.9km. The seismic fault dips to the northwest revealed from the profile parallel to this aftershock sequence, which is identical to the dip of the secondary fault of the NE-trending Menglian-Mojiang fault in the earthquake area. There are more earthquakes concentrated in the northwest segment than in the southeast segment, which is perhaps related to the underground medium and faults. The depth profile of the earthquake sequence shows that the relocated earthquakes are mainly located near the Pu’er fault and the seismic faults dip to the southwest, consistent with the dip of the west branch of the Pu’er fault. In all, the fault strike revealed by earthquake relocations matches well with the strike in the focal mechanism solutions. The main shock is in the top of the aftershock sequence and the aftershocks are symmetrically distributed, showing that faulting was complete in both the NE and SW directions. 相似文献
18.
On August 8, 2017, Beijing time, an earthquake of M7.0 occurred in Jiuzhaigou County, Aba Prefecture, Sichuan Province, with the epicenter located at 33.20°N 103.82°E. The earthquake caused 25 people dead, 525 people injured, 6 people missing and 170000 people affected. Many houses were damaged to various degrees. Up to October 15, 2017, a total of 7679 aftershocks were recorded, including 2099 earthquakes of M ≥ 1.0.
The M7.0 Jiuzhaigou earthquake occurred in the northeastern boundary belt of the Bayan Har block on the Qinghai-Tibet Plateau, where many active faults are developed, including the Tazhong Fault(the eastern segment of the East Kunlun Fault), the Minjiang fault zone, the Xueshan fault zone, the Huya fault zone, the Wenxian fault zone, the Guanggaishan-Daishan Fault, the Bailongjiang Fault, the Longriuba Fault and the Longmenshan Fault. As one of the important passages for the eastward extrusion movement of the Qinghai-Tibet Plateau(Tapponnier et al., 2001), the East Kunlun fault zone has a crucial influence on the tectonic activities of the northeastern boundary belt of Bayan Kala. Meanwhile, the Coulomb stress, fault strain and other research results show that the eastern boundary of the Bayan Har block still has a high risk of strong earthquakes in the future. So the study of the M7.0 Jiuzhaigou earthquake' seismogenic faults and stress fields is of great significance for scientific understanding of the seismogenic environment and geodynamics of the eastern boundary of Bayan Har block.
In this paper, the epicenter of the main shock and its aftershocks were relocated by the double-difference relocation method and the spatial distribution of the aftershock sequence was obtained. Then we determined the focal mechanism solutions of 24 aftershocks(M ≥ 3.0)by using the CAP algorithm with the waveform records of China Digital Seismic Network. After that, we applied the sliding fitting algorithm to invert the stress field of the earthquake area based on the previous results of the mechanism solutions. Combining with the previous research results of seismogeology in this area, we discussed the seismogenic fault structure and dynamic characteristics of the M7.0 Jiuzhaigou earthquake. Our research results indicated that:1)The epicenters of the M7.0 Jiuzhaigou earthquake sequence distribute along NW-SE in a stripe pattern with a long axis of about 35km and a short axis of about 8km, and with high inclination and dipping to the southwest, the focal depths are mainly concentrated in the range of 2~25km, gradually deepening from northwest to southeast along the fault, but the dip angle does not change remarkably on the whole fault. 2)The focal mechanism solution of the M7.0 Jiuzhaigou earthquake is:strike 151°, dip 69° and rake 12° for nodal plane Ⅰ, and 245°, 78° and -158° for nodal plane Ⅱ, the main shock type is pure strike-slip and the centroid depth of the earthquake is about 5km. Most of the focal mechanism of the aftershock sequence is strike-slip type, which is consistent with the main shock's focal mechanism solution; 3)In the earthquake source area, the principal compressive stress and the principal tensile stress are both near horizontal, and the principal compressive stress is near east-west direction, while the principal tensile stress is near north-south direction. The Jiuzhaigou earthquake is a strike-slip event that occurs under the horizontal compressive stress. 相似文献
19.
采用震源位置和速度结构联合反演的方法对大同震区1989年6.1级、1991年5.8级、1999年5.6级3次地震地震序列进行了震源位置和震源区速度结构反演,以确定3次地震序列的分布和震源区的速度结构。结果表明:3次地震序列的发震断裂为NNE向的大王村断裂和NWW向的团堡断裂,两条断裂表现为交替发震;3次地震序列的震源深度平均为10.06 km,其中以6~15 km为发震优势层;研究区速度结构与大的地貌特征相符,沿大同盆地第四纪沉积层表现的不间断低速带,从大同县一直延伸到阳高、天镇等地。在中部山自皂台附近出现了一高速区位置与大同火山群分布区相近。大同—阳高3次地震序列分布在相对高速区上,表明这一区域为应力集中地区。 相似文献
20.
2013年9月24日巴基斯坦俾路支省(Balochistan)境内的阿瓦兰县(Awaran)发生了Mw7.7级地震.本文利用覆盖该地区的Landsat 8数据,基于影像配准的方法获取了该次地震的同震形变场,并运用地统计的方法对形变结果进行精度评定.针对传统四叉树算法中近场和远场中采样密度的不均匀性,以及噪音区域对数据降采样和反演结果收敛性的影响,本文提出了改进的四叉树算法对点的密度和形变梯度进行合理兼顾.最后利用光学影像获取的形变结果和数据的精度水平,基于Okada弹性半空间形变模型反演了该地震的震源参数和断层滑动分布.结果表明,地震断层北倾47°,滑动以左旋走滑为主,断层的西南部兼具少量的倾滑运动分量,断层滑动主要集中分布在断层面0~15km深度范围,最大滑动量达10m.反演获得的地震标量矩为4.68×1020 N·m,震级约为Mw7.75级.本文的研究结果可以为该地区的地壳应力变化研究和地震灾害评估提供依据,同时为Landsat 8光学影像应用于地震的形变研究提供参考. 相似文献