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1.
The deep structure background of earth medium for strong earthquakes occurrence in Yunnan area is discussed in this paper, by using the results on the study of the velocity structure, electrical conductivity structure, geothermal structure in the crust and upper mantle in Yunnan area. The results show that the occurrence of strong earthquakes in Yunnan region is obviously related to the deep medium and tectonic environment such as the existence of the high velocity zone in the upper crust, the low velocity zone or high electrical conductivity layer in the middle crust, local uplift in the upper mantle, high geothermal activity and deep and large fault, etc. The M6 large earthquakes could not take place at anywhere, they often occur at some regions which have a certain background in the deep medium structure. The activity of the earthquakes with magnitude of 5 or less is quite random, the occurrence of them have not the obvious background of the deep medium structure. 相似文献
2.
In this paper changes in focal mechanisms) parameters of wave spectra, and stress drops for the Ms=5.0 forcshock and Ms=6.0 mainshock in February 2001 in Yajiang County, Sichuan, and seismicity in cpiccntral region are studied. Comparison of focal mechanisms for the Yajiang earthquakes with distribution patterns of aftcrshocks, the nodal plane Ⅰ, striking in the direction of NEN, of the Yajiang M=5.0 event is chosen as the faulting plane, the nodal plane Ⅱ, striking in the direction of WNW, of the M=6.0 event as the faulting plane. The strikes of the two faulting planes are nearly perpendicular to each other. The level of stress drops in the cpicentral region before the occurrence of the M=6.0 earthquake increases, which is consistent with increase of seismicity in the epicentral region. The rate decay of the Yajiang earthquake sequence, changes in wave spectra for foreshocks and aftershocks,and focal mechanisms are complex. 相似文献
3.
Crustal structure beneath the Songpan—Garze orogenic belt 总被引:2,自引:0,他引:2
The Benzilan-Tangke deepseismic sounding profile in the western Sichuan region passes through the Song-pan-Garze orogenic belt with trend of NNE.Based on the travel times and the related amplitudes of phases in the record sections,the 2-D P-wave crustal structure was ascertained in this paper.The velocity structure has quite strong lateral variation along the profile.The crust is divided into 5layers,where the first,second and third layer belong to the upper crust,the forth and fifth layer belong to the lower crust.The low velocity anomaly zone gener-ally exists in the central part of the upper crust on the profile,and it integrates into the overlying low velocity basement in the area to the north of Ma‘erkang.The crustal structure in the section can be divided into 4parts:in the south of Garze-litang fault,between Garze-Litang fault and Xianshuihe fault,between Xianshuihe fault and Longriba fault and in the north of Longriba fault,which are basically coincided with the regional tectonics division.The crustal thickness decreases from southwest to northeast along the profile,that is ,from62km in the region of the Jinshajiang River to 52km in the region of the Yellow River.The Moho discontinuity does not obviously change across the Xianshuihe fault basesd on the PmP phase analysis.The crustal average velocity along the profile is lower,about 6.30 km/s.The Benzilan-Tangke profile reveals that the crust in the study area is orogenic.The Xianshuihe fault belt is located in the central part of the profile,and the velocity is positive anomaly on the upper crust,and negative anomaly on the lower crust and upper mantle.It is considered as a deep tectonhic setting in favor of strong earthquake‘s accumulation and occurrence. 相似文献
4.
S-wave velocity and Poisson's ratio structure of crust in Yunnan and its implication 总被引:13,自引:2,他引:11
HU Jiafu SU Youjin ZHU Xiongguan & CHEN Yun Geophysical Department of Yunnan University Kunming China Seismological Bureau of Yunnan Province Kunming China Institute of Geology Geophysics Chinese Academy of Sciences Beijing China 《中国科学D辑(英文版)》2005,48(2):210-218
Receiver function of body wave under the 23 stations in Yunnan was extracted from 3-component broadband digital recording of teleseismic event. Thus, the S-wave velocity structure and distribution characteristics of Poisson's ratio in crust of Yunnan are obtained by inversion. The results show that the crustal thickness is gradually thinned from north to south. The crustal thickness in Zhongdian of northwest reaches as many as 62.0 km and the one in Jinghong of further south end is only 30.2 km. What should be especially noted is that there exists a Moho upheaval running in NS in the Chuxiong region and a Moho concave is generally parallel to it in Dongchuan. In addition, there exists an obvious transversal inhomogeneity for the S-wave velocity structure in upper mantle and crust in the Yunnan region. The low velocity layer exists not only in 10.0-15.0 km in upper crust in some regions, but also in 30.0-40.0 km in lower crust. Generally, the Poisson's ratio is on the high side, however it has a better co 相似文献
5.
The Wudalianchi volcano is a modern volcano erupted since the Holocene.Its frequent occurrence of the small earthquake is considered to be indicator of active dormancy volcano.The S wave velocity structure is inferred from the receiver function for the crust and upper mantle of the Wudalianchi volcano area.The results show that the low velocity structure of Swave is widely distributed undemeath the volcano area and part of the low-velocity-zone located at shallow depth in the Wudalianchi volcano area.The low velocity structure is related to the seismicity.The Moho interface is not clear undemeath the volcano area,which may be regard to be an nec-essary condition for the lava upwelling.Therefore,we infer that the Wudalianchi volcano has the deep structural condition for the volcano activity and may be alive again. 相似文献
6.
A study on physical property of crustal ma—terial and seismogenic environment in northeastern Pamir 总被引:1,自引:0,他引:1
2-D crustal structure and velocity ratio are obtained by processing S-wave data from two wide-angle reflec-tion/refraction profiles in and around Jiashi in northeastern Pamir,with the result of P-wave data taken into con-sideration.The result shows that:1)Average crustal velocity ratio is obviously higher in Tarim block than in West Kunlun Mts.and Tianshan fold zone,which reflects its crustal physical property of “hardness“and stability.The relatively low but normal velocity ratio(Poisson‘s ratio)of the lower crust indicates that the “downward thrusting“ of Tarim basin is the main feature of crustal movement in this area.2)The rock layer in the upper crust of Tian-shan fold zone is relatively“soft“,which makes it prone to rupture and stress energy release.This is the primary tectonic factor for the concentration of small earthquakes in this area.3)Jiashi is located right over the apex or the inflection point of the updoming lower crustal interface C and the crust-mantle boundary,which is the deep struc-tural background for the occurrence of strong earthquakes.The alternate variation of vp/vs near the block bounda-ries and the complicated configuration of the interfaces in the upper and middle part of the upper crust form a par-ticular structural environment for the Jiashi strong earthquake swarm.vp/vs is comparatively high and shear modulus is low at the focal region,which may be the main reason for the low stress drop of the Jiashi strong earthquake swarm. 相似文献
7.
Shear velocity structure of crust and uppermost mantle in China from surface wave tomography using ambient noise and earthquake data 总被引:1,自引:0,他引:1
We present a 3D model of shear velocity of crust and upper mantle in China and surrounding regions from surface wave tomography.We combine dispersion measurements from ambient noise correlation and traditional earthquake data.The stations include the China National Seismic Network,global networks,and all the available PASSCAL stations in the region over the years.The combined data sets provide excellent data coverage of the region for surface wave measurements from 8 to 120 s,which are used to invert for 3D shear wave velocity structure of the crust and upper mantle down to about150 km.We also derive new models of the study region for crustal thickness and averaged S velocities for upper,mid,and lower crust and the uppermost mantle.The models provide a fundamental data set for understanding continental dynamics and evolution.The tomography results reveal significant features of crust and upper mantle structure,including major basins,Moho depth variation,mantle velocity contrast between eastern and western North China Craton,widespread low-velocity zone in midcrust in much of the Tibetan Plateau,and clear velocity contrasts of the mantle lithosphere between north and southern Tibet with significant E–W variations.The low velocity structure in the upper mantle under north and eastern TP correlates with surface geological boundaries.A patch of high velocity anomaly is found under the eastern part of the TP,which may indicate intact mantle lithosphere.Mantle lithosphere shows striking systematic change from the western to eastern North China Craton.The Tanlu Fault appears to be a major lithosphere boundary. 相似文献
8.
A genetic algorithm of body waveform inversion is presented for better understanding of crustal and upper mantle structures with deep seismic sounding (DSS) waveform data. General reflection and transmission synthetic seismogram algorithm, which is capable of calculating the response of thin alternating high and low velocity layers, is applied as a solution for forward modeling, and the genetic algorithm is used to find the optimal solution of the inverse problem. Numerical tests suggest that the method has the capability of resolving low-velocity layers, thin alternating high and low velocity layers, and noise suppression. Waveform inversion using P-wave records from Zeku, Xiahe and Lintao shots in the seismic wide-angle reflection/refraction survey along northeastern Qinghai-Xizang (Tibeteau) Plateau has revealed fine structures of the bottom of the upper crust and alternating layers in the middle/lower crust and topmost upper mantle. 相似文献
9.
The complexity feature of crust-mantle boundary in Zhangbei seismic region and its tectonic implication 总被引:1,自引:0,他引:1
The ProP waveform data obtained from a deep seismic sounding profile, which ran through Zhangbei seismic region, were processed by means of both seismic wave complexity coefficient and frequency spectrum analysis methods, and the complexity characteristics of crest-mantle boundary beneath the studied area and its adjacent region were determined. The results show that the place below epicenter can be taken as boundary, the northern side of which is Inner Mongolia axis with small complexity coefficient and the southern side of which is Huai'an basin with large complexity coefficient. The different spectrum patterns at the two sides of the epicenter were inferred from spectrum analysis. In the epicentral area, there have been multi-period magmatic eruptions since Meso-Cenozoic and craters exist at the surface. From the velocity imaging of middle and upper crust in Zhangbei seismic region it can be found that there are crustal low velocity bodies around the craters and also there are low velocity zones, which went into deep crust. It is suggested that the distinct zones of crust-mantle boundary complexity may be the margin, where the magma had intruded due to magma activity in Meso-Cenozoic. The southern side with large complexity coefficient is deep magmatic activity area and the northern side with small complexity coefficient is stable crust-mantle tectonics. The difference of crust-mantle complexity provides deep background for the development of strong earthquake. 相似文献
10.
Study on Fine Crustal Structure of the Sanhe-Pinggu Earthquake (M8.0) Region by Deep Seismic Reflection Profiling 总被引:2,自引:1,他引:2
Zhang Xiankang Zhao Jinren Liu Guohu Song Wenrong Liu Baojin Zhao Chengbin Cheng Shuangxi Liu Jian Gu Menglin Sun Zhenguo 《中国地震研究》2003,17(2):122-133
Two near-vertical deep seismic reflection profiles (140km-long, 24-fold) were completed in the 1679 Sanhe-Pinggu earthquake (M8.0) region. The profiles ran through the Xiadian fault and the Ershilichangshan fault. The profiling result shows that the crust in this region is divided into the upper crust, the lower crust and the crust-mantle transitional zone by two powerful laminated reflectors: one at the two-way travel-time of about 7.0s (21 km), the other at about11.0~12.5s (33~37km). Crustal structure varies significantly in vertical direction. The shallow part is characterized by obvious stratification, multilayers and complexity. The upper crust on the whole features reflection “transparency“, while the lower crust features distinct reflectivity. Crustal structure also varies a lot in the lateral direction. The main fracture in this region is the deep fault under the Xiadian fault. This deep fault is steeply inclined (nearly vertical), and is supposed to be the causative fault of the Sanhe-Pinggu MS.0 earthquake. The two profiles respectively reveal the existence of local strong reflectivity in the lower crust and the lower part of the upper crust, which is assumed to be a dike or rock mass formed by the upwelling and cooling down of materials from the upper mantle. Magmatic activity in this part brought about differences in regional stress distribution, which then gave rise to the formation of the deep fault. That is supposed to be the deep structural setting for the Sanhe-Pinggu M8.0 earthquake. 相似文献
11.
12.
From the magnetotelluric detection in the epicentral region and the adjacent areas of the 1605 M7.5 Qiongzhou earthquake, we have discovered there is a low resistive body in the deep crust of the epicentral region. The low resistive body extends straightly from the depth of about 13 km to the upper mantle, which is supposed as an uprising mantle pole. We therefore consider it is just the existing mantle pole and its upwelling thermal material that result in the faulting and stick-slipping activities of the upper crust, which is an important factor for the M7.5 Qiongzhou great earthquake occurrence. The postseismic faulting activity is characterized by creep, which shows that the risk is greatly decreased for the occurrence of a great earthquake with similar intensity in the future. 相似文献
13.
雷琼火山区地下深部大地电磁探测与电性结构分析 总被引:4,自引:0,他引:4
通过大地电磁探测发现,在海口地区地下深部存在两个低阻体(层),其一位于马鞍岭火山及其以西地区地下深部约5km以上,为浅部低阻层,推测为火山喷出玄武岩覆盖体、地下水及其它低阻物质,该低阻层以下为一正在退化的岩浆通道;其二位于琼山7.5级地震区深部约15km以下,为一直通到上地幔的深部低阻体,推测其为一正在上升的岩浆热源,即岩浆囊。另外还发现,琼州海峡南北两侧的地壳和上地幔结构在电性上具有连续性,推测整个雷琼火山区属于同一地质体,佐证了海南岛属于华南古陆的一部分。 相似文献
14.
研究了2001年2月四川省雅江县发生的MS5.0前震、MS6.0主震及序列地震的震源机制、波谱参数及应力降的变化过程与震区地震活动.根据雅江地震的震源机制解,并结合余震空间分布图象分析,选雅江5.0级的节面Ⅰ为推测的地震断层,走向NNE;选雅江6.0级地震的节面Ⅱ为推测的地震断层,走向WNW,分析前震与主震的断层面走向是斜交的.雅江6.0级地震发生前震区应力降水平有所增加,这一现象与震区地震活动的增加是一致的.雅江地震序列的衰减起伏过程, 前、余震波谱变化, 以及震源力学错动机制等均呈现复杂特征. 相似文献
15.
本文对唐山地震区的深地震测深资料进行了分析解释。结果表明,该区地壳结构的几个特点,与大陆地区的强震发生有明显关系。 在该震区,相应于不同记录剖面的不同地段,其地壳结构可分为三种类型:类型Ⅰ,类型Ⅱ和类型Ⅲ。每种类型都有它们独特的速度——深度分布。在两种类型的地壳结构边界,或者边界附近,通常存在莫霍界面深度的急剧变化,这种变化可视为某种类型的断层。上述三种类型地壳结构的差异,主要是由上地幔物质向地壳的垂直迁移程度不同造成的。震中区的地壳结构,显示出极高度的物质迁移。然而,应该指出,现今地壳结构是在漫长的地质年代里,经过多次变形积累而形成的。因此,这种结构特征,是表示过去的构造活动痕迹,还是表示现今的构造活动,尚难定论。如我们将不同类型地壳结构的边界,与剥去第三纪的地质构造图进行对比,可以发现,不同地壳结构类型的分界,恰与一定的古老地质构造边界相符合。象北京——天津——唐山这样距离海洋不远的地区,古老的不同种类的小地质体,可能在古代的全球构造运动中聚集起来,并粘结在一起。 1976年唐山主震发生在地壳结构类型Ⅱ内、靠近类型Ⅰ的边界处。因此,唐山地震可能是由于上地幔物质向上迁移的结果,也可能是由于板块的横向挤压、引起脆弱边界重新活化的结果。另有一点是, 相似文献
16.
Introduction An MS=6.0 earthquake occurred on February 23, 2001 in Yajiang county, Sichuan Province. The earthquake is located on the east of the southeast segment of the Litang-Dewu fault with strike of NW. Before the event, on February 14, an MS=5.0 earthquake took place nearly in the same place. In 1948 an MS=7.3 earthquake occurred on the northwestern segment of the Litang fault. The length of the surface rupture belt caused by the earthquake is 70 km, which extended from Litang to… 相似文献
17.
通过唐山震中的地震测深以及深反射剖面,揭示了唐山震源区的浅部及深部构造图象,它与以往的推测很不相同。 唐山东面的开平向斜属中生代构造,探测的结果表明,向斜轴是一近于直立的地壳断裂。唐山地震时的水平地形变主要是由开平地壳断裂的位移引起的,它是北北东-南南西向右旋走滑断裂。开平地壳断裂西面的陡河断层是一自地表向南东方向下插的正断层,断层倾角为26°,延伸至5km深处。陡河正断层刚好插到唐山市震中区的正下方。唐山地震时的垂直地形变主要是由陡河正断层的滑动引起的。 野鸡坨-丰台断层通过震源区的西部边缘,断层以西的第四纪沉积层,在过去一百万年间曾经沿北北东方向水平滑移15km,表明它也是一个右旋的走滑断层。但是它在近代数百年间并无地震活动,唐山地震时该断层的滑动亦不明显。 开平地壳断裂和陡河正断层在唐山地震时同时滑动,说明地震的作用力除区域水平构造力外,地壳上方还存在一个附加的引张力。在开平断裂处,上部地壳的反射面倾角杂乱,而且在它的正下方,莫霍界面明显错断,因此,地幔顶部的热物质可能自开平地壳断裂中上升。热物质产生的热应力在地壳上方可表现为张应力,而在地壳下方却表现为压应力,这与反射地震剖面图的现象相符合。开平地壳断裂中热物质的上升对地震的产生有 相似文献
18.
由50余个测点的大地电磁测深资料,讨论了该区的地壳-上地幔电性横向变化特征。按照上地幔第一低阻层顶面埋深,将测区划分为四类地区:浅埋深(55-90公里)、中浅埋深(90-110公里)、中深埋深(110-160公里)和深埋深(160-250公里)。讨论了本区六次大震例的深部电性背景。指出了上地幔顶部的梯度带地区、地壳内电性横向变化剧烈的地区和地壳内存在局部特殊增厚的低阻层地区将可以作为潜在震源区的深部电性判据之一 相似文献
19.
Li Songlin Zhang Xiankang Zhang Chengke Ren Qingfang Shi Jinhu Zhao Jinren Fang Shengming Liu Baofeng Pan Suzhen Zhang Jianshi 《中国地震研究》2001,15(3):230-238
INTRODUCTIONXIJI-Halyuan-Zhon驯el region Is a well-known eaythquake-prone one In China.From 876 to1989,IOrty-five earthquakes with M。34.7 occurred In and around the。glon(Ma Xingyuan,et al,1989).Seismic activity In this area Is evidently cha。cterized by large matlnltude and high frequency.The 1920 Haiyuan earthquake(M=8.5)happened nght In this region,which caused a seriousdisaster and had a wide-ranging effect seldom seen worldwide.For the years,lots of… 相似文献
20.
1605年琼州地震,是迄今发生在我国海南岛地区仅有的一次大地震.对该次地震震害特征和发震构造的深入研究,将有助于正确评定该地区的地震危险性;对研究南海北部陆缘地带的地震特征和发震构造,具有重要意义. 本文作者在雷琼地区进行了详细的实地考察,发现了大批记载本次大震情景和震害状况的家谱、族谱和碑记;发现并证实了该次地震所造成的大规模陆陷成海的遗墟.本项研究结果认为,1605年琼州大地震的震中烈度达ⅩⅠ度;震级为7 1/2——8级;震中位于琼山县塔市附近(北纬20,东经110.5). 对震源区地质构造和地球物理场的研究结果表明,该次大地震的发震断裂为NEE走向的光村——铺前深断裂和NNW走向的塔市——演丰断裂(以前者为主);该次大地震是水平构造应力(主压应力轴方向为NWW300左右)和垂直构造应力共同作用的结果;垂直向构造应力在大震发生和造成大规模陆陷成海过程中起着主要作用. 重、磁等地球物理场特征研究结果还表明,1605年琼州大地震的发生,不是单纯地壳构造断裂的结果,而是深部地球物理场在此震源区的特殊构造部位,由于主要震源断裂两盘重力场特征不同的构造块体物质密度,即重力场源的差异,在重力均衡补偿调整的过程中,上地幔的隆起与拗陷的差异升降、岩浆物质的差异运动,以及热动力的差异运动的复合结果. 相似文献