共查询到20条相似文献,搜索用时 0 毫秒
1.
Introduction The 1303 Hongtong earthquake is an important earthquake in the eastern China. There is a lot of information in historical documents about the earthquake and many traces destroyed by the earthquake in the southern Shanxi Province. Many scholars have studied the earthquake from dif-ferent aspects, but mainly limited the definitions of the isoseismal and three factors of the earth-quake. Owing to being limited by the analysis technique, many useful damage information of the earthqu… 相似文献
2.
3.
Based on the latest displacement of Huoshan piedmont fault, Mianshan west-side fault and Taigu fault obtained from the beginning of 1990‘s up to the present, the characteristics of distribution and displacement of surface rupture zone of the 1303 Hongtong M = 8 earthquake, Shanxi Province are synthesized and discussed in the paper. If Taigu fault, Mianshan west-side fault and Huoshan piedmont fault were contemporarily active during the 1303 Hongtong M = 8 earthquake, the surface rupture zone would be 160 km long and could be divided into 3 segments, that is, the 50-km-long Huoshan piedmont fault segment, 35-km-long Mianshan west-side fault segment and 70-km-long Taigu fault segment, respectively. Among them, there exist 4 km and 8 km step regions. The surface rupture zone exhibits right-lateral features. The displacements of northern and central segments are respectively 6~7 m and the southern segment has the maximum displacement of 10 m. The single basin-boundary fault of Shanxi fault-depression system usually corresponds to M ≈ 7 earthquake, while this great earthquake (M = 8) broke through the obstacle between two basins. It shows that the surface rupture scale of great earthquake is changeable. 相似文献
4.
1303年在山西洪洞附近发生的8级巨大地震, 是中国根据现存较为详细的文献记载史料所确定的最早的一次8级地震。 这次地震距今已有700多年的历史, 而地震所在区域至今仍有持续不断的小地震活动。 本文根据地震破裂区1981年至2013年的中小地震精定位地震目录, 采用震源断层面拟合方法, 反演得到了1303年山西洪洞地震的震源断层面参数: 走向19.3°、 倾角88.5°、 滑动角-170.0°。 断层面长75.5 km, 宽26.2 km, 深度为地下11.12 ~37.35 km。 将地震破裂区的地震精确定位资料以近东西向的洪洞断裂为界划分为地震北段和地震南段, 分段进行地震震源断层拟合, 反演得到洪洞地震北段震源断层面参数: 走向13.7°、 倾角76.6°、 滑动角-157.6°。 断层面长32.7 km, 宽21.7 km, 深度为地下11.97~32.86 km; 南段震源断层面参数: 走向20.3°、 倾角87.1°、 滑动角-154.6°。 断层面长45.9 km, 宽16.6 km, 深度为地下9.32 km~25.50 km。 无论是分段还是不分段, 反演得到的洪洞地震震源断层均是右倾的近直立断层, 属于右旋走向滑动性质。 分段计算得到的地震北段震源断层深度比南段更深, 将反演得到的震源断层与临汾盆地深部构造最新研究成果进行了分析对比, 北段震源断层深度及倾角大小与深地震剖面推测得到的深大断裂几乎相同。 震源断层在地表的投影与洪洞地震的高烈度区能够较好地对应。 相似文献
5.
Introduction The 1303 Shanxi Hongtong M=8 earthquake is the earliest M=8 event determined in histori-cal records in China and the largest recorded in Shanxi fault-depression system in history. Some researchers have discussed the tectonic environment of this earthquake (DENG, et al, 1973; DENG, 1984; DENG, XU, 1994, 1995; Seismo-geological Brigade, State Seismological Bureau, Depart-ment of Geology and Geography, Peking University, 1979; LIU, XIAO, 1982; ZHANG, JIA, 1986; SU, … 相似文献
6.
Introduction A great earthquake occurred on Sept. 25 of 1303 (Seventh of Dade, Yuan Dynasty) around Zhaocheng and Hongtong in Shanxi Province. The great earthquake is a very famous one, which is affirmed as the first earthquake with magnitude 8 in Chinese history. The catastrophes took place; meanwhile, huge archives of the disaster were recorded. According to these disaster recordings, the first isoseismal map in China was delineated, which provide us with abundant information of intensi… 相似文献
7.
In this paper, we calculated the seismic pattern of instrumental recorded small and moderate earthquakes near the epicenter of the 1303 Hongtong M=8 earthquake, Shanxi Province. According to the spatial distribution of small and moderate earthquakes, 6 seismic dense zones are delineated. Temporal distribution of ML≥2 earthquakes since 1970 in each seismic dense zone has been analyzed. Based on temporal distribution characteristics and historical earthquake activity, three types of seismicities are proposed. The relationship between seismic types and crustal medium is analyzed. The mechanism of three types is discussed. Finity of strong earthquake recurrence is proposed. Seismic hazard in mid-long term and diversity of earthquake disaster in Shanxi seismic belt are discussed. 相似文献
8.
通过对2017年8月9日精河6.6级地震灾区内共计355个调查点的实地调查,确定了此次地震的烈度分布。灾区最高烈度为Ⅷ度(8度),灾区面积15623km2,灾区总人口487696人,其中,受灾人口133695人,地震共造成36人受伤;对各烈度区内不同结构类型房屋的震害现象进行了整理,分析了不同结构类型房屋的抗震能力与震害原因,结果显示,土木结构房屋倒塌及屋檐塌落是导致人员受伤的主要原因;砖木结构房屋缺乏抗震设施,破坏形式多样;砖混结构房屋在高烈度区破坏较重;框架结构房屋主体完好但填充墙普遍出现破坏。安居富民房屋抗震性能良好。 相似文献
9.
Introduction The Taigu fault is located on the eastern boundary of the Jinzhong basin in the Shanxi fault depression system, which is one of the 12 major active basin boundary faults, and is also less studied among them. The reason for this is, firstly, the Jinzhong basin has no historical earth-quakes with M 7, while the two basins linked together in the northern and southern sides, the Linfen and Xinding basins all have had historical earthquakes with M 7; secondly, because the Jiaochen… 相似文献
10.
The geography information system of the 1303 Hongton M=8 earthquake has been established. Using the spatial analysis function of GIS, the spatial distribution characteristics of damage and isoseismal of the earthquake are studies. By comparing with the standard earthquake intensity attenuation relationship, the abnormal damage distribution of the earthquake is found, so the relationship of the abnormal distribution with tectonics, site condition and basin are analyzed. In this paper, the influence on the ground motion generated by earthquake source and the underground structures near source also are studied. The influence on seismic zonation, anti-earthquake design, earthquake prediction and earthquake emergency responding produced by the abnormal density distribution are discussed. 相似文献
11.
The 1995 Kobe earthquake caused unprecedented damage to buildings and civil infrastructures in the city of Kobe and its surrounding areas. In order to evaluate the structural damage in this area due to the earthquake, it is important to estimate the distribution of earthquake ground motion. However, since the number of strong ground motion records is not enough in the heavily damaged areas, it is necessary to estimate the distribution using other data sources. In this paper, the fragility curves for low‐rise residential buildings were constructed using the recorded motions and the building damage data from the intensive field survey by the AIJ and CPIJ group. The fragility curves obtained were then employed to estimate the strong motion distribution in the district level for Kobe and the surrounding areas during the earthquake. The results may be useful to investigate the various damages caused by the earthquake. Copyright © 2001 John Wiley & Sons, Ltd. 相似文献
12.
The observation of the fault-zone trapped waves was conducted using a seismic line with dense receivers across surface rupture
zone of the M=8.1 Kunlun Mountain earthquake. The fault zone trapped waves were separated from seismograms by numerical filtering and spectral
analyzing. The results show that: a) Both explosion and earthquake sources can excite fault-zone trapped waves, as long as
they locate in or near the fault zone; b) Most energy of the fault-zone trapped waves concentrates in the fault zone and the
amplitudes strongly decay with the distance from observation point to the fault zone; c) Dominant frequencies of the fault-zone
trapped waves are related to the width of the fault zone and the velocity of the media in it. The wider the fault zone or
the lower the velocity is, the lower the dominant frequencies are; d) For fault zone trapped waves, there exist dispersions;
e) Based on the fault zone trapped waves observed in Kunlun Mountain Pass region, the width of the rupture plane is deduced
to be about 300 m and is greater than that on the surface.
Foundation item: Joint Earthquake Science Foundation of China (201001).
Contribution No. RCEG200305, Research Center of Exploration Geophysics, China Earthquake Administration. 相似文献
13.
Based on digital teleseismic P-wave seismograms recorded by 28 long-period seismograph stations of the global seismic network,
source process of the November 14, 2001 western Kunlun Mountain M
S=8.1 (M
W=7.8) earthquake is estimated by a new inversion method. The result shows that the earthquake is a very complex rupture event.
The source rupture initiated at the hypocenter (35.95°N, 90.54°E, focal depth 10 km, by USGS NEIC), and propagated to the
west at first. Then, in several minutes to a hundred minutes and over a large spatial range, several rupture growth points
emerged in succession at the eastern end and in the central part of the finite fault. And then the source rupture propagated
from these rupture growth points successively and, finally, stopped in the area within 50 km to the east of the centroid position
(35.80°N, 92.91°E, focal depth 15 km, by Harvard CMT). The entire rupture lasted for 142 s, and the source process could be
roughly separated into three stages: The first stage started at the 0 s and ended at the 52 s, lasting for 52 s and releasing
approximately 24.4% of the total moment; The second stage started at the 55 s and ended at the 113 s, lasting for 58 s and
releasing approximately 56.5% of the total moment; The third stage started at the 122 s and ended at the 142 s, lasting for
20 s and releasing approximately 19.1% of the total moment. The length of the ruptured fault plane is about 490 km. The maximum
width of the ruptured fault plane is about 45 km. The rupture mainly occurred within 30 km in depth under the surface of the
Earth. The average static slip in the underground rocky crust is about 1.2 m with the maximum static slip 3.6 m. The average
static stress drop is about 5 MPa with the maximum static stress drop 18 MPa. The maximum static slip and the maximum stress
drop occurred in an area within 50 km to the east of the centroid position.
Foundation item: Joint Seismological Science Foundation of China (103066) and Foundation of the Seismic Pattern and Digital Seismic Data
Application Research Office of Institute of Earthquake Science of the China Earthquake Administration. 相似文献
14.
We have selected 171 near-field records from 391 aftershock records of the Lulong, Hebei Province, earthquake in October 1982
and relocated the hypocenter of 45 aftershocks using the program Hypoinverse. The distribution of aftershocks reveals a set
of earthquake faults: a WNW stretching fault truncates two NNE stretching faults. The two branches of faults show the conjugate
structure which is often seen in brittle fracture. The NNE stretching faults are connected together. The Luanhe river valley
near Lulong developed to a rudiment rift basin surrounded by a series of faults. The fault of Lulong earthquake is a strike-slip
fault with tension component. This fault type matches with the activity of Zhangjiakou-Bohai seismic belt (Zhang-Bo belt)
and also shows the action of Zhang-Bo belt as a boundary of two secondary active blocks that truncates the NNE fault.
Foundation item: National Natural Science Foundation of China (40234038).
Contribution No. 05FE3016, Institute of Geophysics, China Earthquake Administration. 相似文献
15.
Based on the analysis of coseismic deformation in the macroscopic epicentral region extracted by Differential Interferometric
Synthetic Aperture Radar (D-InSAR), and combined with the seismic activity, focal mechanism solutions of the earthquake and
field investigation, the characteristic of coseismic deformation of M
S=8.1 western Kunlunshan Pass earthquake in 2001 was researched. The study shows that its epicenter lies in the northeast side
of Hoh Sai Hu; and the seismogenic fault in the macroscopic epicentral region can be divided into two central deformation
fields: the west and east segments with the lengths of 42 km and 48 km, respectively. The whole fault extends about 90 km.
From the distribution of interferometry fringes, the characteristic of sinistral strike slip of seismogenic fault can be identified
clearly. The deformations on both sides of the fault are different with an obviously higher value on the south side. In the
vicinity of macroscopic epicenter, the maximum displacement in look direction is about 288.4 cm and the minimum is 224.0 cm;
the maximum sinistral horizontal dislocation of seismogenic fault near the macroscopic epicenter is 738.1 cm and the minimum
is 551.8 cm.
Foundation item: National Natural Science Foundation of China (40374013) and “Researching on the Disaster Earthquake” (2003) of Public Welfare
Research Item, Ministry of Science and Technology of China. 相似文献
16.
Wang Shuang-xu Jiang Zai-sen Chen Wen-sheng Zhang Xi Chen Bing Zhang Si-xin Wang Ji-ying 《地震学报(英文版)》2001,14(2):156-165
The time-space distribution characteristics of fault deformation anomaly in the near-source region and its outlying zone in
the seismogenic process of the Jingtai M
s=5.9 earthquake occurred on June 6, 2000 in Gansu Province is studied preliminarily. The distribution scope of fault deformation
anomaly before the earthquake is wide, the anomaly shape is complicated and the pattern anomalous zone of fault deformation
(strain) information index is obvious. The shape and amplitude of fault deformation anomaly in different regions differ significantly,
which is closely related with the tectonic location of anomaly. The fault deformation anomaly of α, β, and γ phases along
the western segment of Haiyuan fault zone shows the process from the quasi-linearity to non-linearity of fault movement in
the near-source region, matches the high-value anomalous area of fault deformation (strain) information index, and reflects
the high strain accumulation in the seismogenic region. However, the anomaly of abrupt jump and cusp with a large amplitude
occurred in the areas far from the earthquake, such as Liupanshan fault zone which is the tectonic convergent section does
not reflect the strain accumulation of its location, maybe it is a sign that the regional tectonic stress field is strengthened
in the seismogenic process. Based on the above-mentioned facts and combined with the preliminary summary of experiences and
lessons in the intermediate and short-term prediction of the Jingtai M
s=5.9 earthquake, we study and explore the application of fault deformation anomaly to earthquake judgment.
Foundation item: National Key Basic Research Development Program (G1998040703 and G1998040705), and State Scientific and Technological Project
of the “Ninth Five-Year Plan” (96-913-09-01-02-03 and 96-913-09-02-02-03), China. 相似文献
17.
The Taigu fault zone is one of the major 12 active boundary faults of the Shanxi fault-depression system, located on the eastern
boundary of the Jinzhong basin. As the latest investigation indicated, the fault zone had dislocated gully terrace of the
first order, forming fault-scarp in front of the loess mesa. It has been discovered in many places in ground surface and trenches
that Holocene deposits were dislocated. The latest activity was the 1303 Hongdong earthquake M=8, the fault appeared as right-lateral strike-slip with normal faulting. During that earthquake, the Taigu fault together
with the Mianshan western-side fault on the Lingshi upheaval and the Huoshan pediment fault on the eastern boundary of the
Linfen basin was being active, forming a surface rupture belt of 160 km in length. Moreover, the Taigu fault were active in
the mid-stage of Holocene and near 7 700 aB.P. From these we learnt that, in Shanxi fault-depression system, the run-through
activity of two boundary faults of depression-basins might generate great earthquake with M=8.
Foundation item: Chinese Joint Seismological Science Foundation (201017).
Contribution No. 2003A004, Institute of Crust Dynamics, China Earthquake Administration. 相似文献
18.
Comparison of strong-motion records and damage implications between the 2014 Yunnan M_S6.5 Ludian earthquake and M_S6.6 Jinggu earthquake 
下载免费PDF全文
下载免费PDF全文 Serial destructive earthquakes have caused heavy casualties and economic losses to the city in southwestern of China. The Ludian M_s 6.5 earthquake and the Jinggu M_s6.6 earthquake occurred in Yunnan province in 2014. There is a question of why the two events with almost the same level of magnitude caused differences in earthquake damage. To understand the uniqueness of the phenomenon,this paper focuses on the characteristics of the ground motions and post-earthquake field investigation for the two events.Firstly, we present an overview of the residuals between the Ludian earthquake and the Jinggu earthquake based on the YW06 Ground Motion Prediction Equation(GMPE), and explain the unusual destructiveness of the strong ground motion. Then we analyze the ground motion recordings at selected typical station, based on the strong motion parameters: equivalent predominant frequency and Arias intensity. The result exhibits a good agreement with the Chinese seismic intensity scale. This study would be helpful to gain a better knowledge of the characteristics and variability of ground motions for M_S6 class earthquakes in China and to understand the implications to future earthquakes with similar focal mechanism and local condition. 相似文献
19.
The continuous GPS observation at the fiducial stations in the Crustal Movement Observation Network of China (CMONOC) recorded
the crustal movement of Chinese mainland before and after the great Kunlun Mountain earthquake of M=8.1 on November 14, 2001, especially the horizontal crustal movement in the western part of China. Based on the datum defined
by a group of stable stations with small mutual horizontal displacements for a few years, the time series of horizontal displacements
at fiducial stations were obtained. Significant anomalous horizontal displacements had appeared at the fiducial stations in
the western part of China since early November 2000 and several earthquakes with the magnitudes about 6.0 had occurred in
Yunnan and Sichuan Provinces. The northward components of the horizontal displacement at the fiducial stations in west China
had decreased significantly and even changed in the opposite sense since mid April 2001. After the earthquake, the northward
displacements still decreased and there were significant westward displacements. The process of the crustal movement in the
western part of Chinese mainland (in reference to east China) suggests that the main force source for this earthquake came
from the northward pushing of the Indian plate. The great earthquake released a large amount of energy, as a result, the action
applied by the Indian plate to Chinese mainland diminished significantly and after the great earthquake, the seismic activity
in Chinese mainland decreased considerably until the end of 2002.
Foundation item: The National Development and Programming Project for Key Basic Research (95-13-03-07). 相似文献
20.
Long-term seismic activity prior to the December 26, 2004, off the west coast of northern Sumatra, Indonesia, M
W=9.0 earthquake was investigated using the Harvard CMT catalogue. It is observed that before this great earthquake, there
exists an accelerating moment release (AMR) process with the temporal scale of a quarter century and the spatial scale of
1 500 km. Within this spatial range, the M
W=9.0 event falls into the piece-wise power-law-like frequency-magnitude distribution. Therefore, in the perspective of the
critical-point-like model of earthquake preparation, the failure to forecast/predict the approaching and/or the size of this
earthquake is not due to the physically intrinsic unpredictability of earthquakes.
Foundation item: Ministry of Science and Technology Project (2004CB418406).
Contribution No. 05FE3010, Institute of Geophysics, China Earthquake Administration. 相似文献
