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腾冲火山地区的地震活动特征 总被引:5,自引:0,他引:5
对腾冲火山地区的地震活动时空分布及震情参数的研究结果表明,与火山活动区有关的地震活动具有以下特征:周围构造地震活动频繁而火山群地区则处于地震活动相对平静的背景,震级较低(最高为5.0~6.0级);地震活动以小的震群活动为主,微震主要发生在腾冲县城南部的热海热田地区。长期的地震频率b值高,达1.2左右;震源深度在0~20km范围,受周围构造大地震的影响,导致火山区地壳内部岩浆活动引起的岩浆冲击型地震发生;火山体地下低速层的存在与地下热物质有关。从腾冲火山活动区地震的时空分布特征和震情参数特征表现出与世界上其它火山地震的相似关系,表明腾冲火山不是死火山,火山体地壳内部存在的岩浆囊或岩浆移动通道内岩浆仍在活动。 相似文献
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在五大连池火山区流体化学研究原有工作的基础上,对火山群的重要区段开展了野外踏勘、气体普查,特别是用放射性气体测量方法对火烧山、老黑山、笔架山、药泉山等火山区进行了Tn、Rn测量。通过大量实测资料,分析和研究了Tn、Rn等气体和火山、火山活动、断裂构造、断裂活动性及其他地质条件的关系,初步查明了五大连池火山区的气体组成特征、分布和形成规律,对地下主要气体的成因、气体和火山构造活动及其它地质条件的关系进行了初步探讨,并提出了对五大连池火山区气体观测的初步设想和建议。 相似文献
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五大连池火山区的地震活动特征及其成因的初步探讨 总被引:1,自引:0,他引:1
通过对1981~1988年这一时期内五大连池火山区的地震和人工爆破记录的分析和整理,讨论了本区的岩浆侵入活动,总结了本区的地震活动特征,并对本区内地震活动成因机制进行了初步的探讨。结果表明:五大连池火山活动与地震活动存在着密切的联系,它们有着共同的成因机制即本区的岩浆侵入活动,火山区地震活动的不同特征反映着火山的活动性。火山区的小震及微震是由于岩浆侵入时期岩浆充填地下微裂隙和岩浆回落时期穹窿塌陷所致;火山区外围的中强地震是由于岩浆侵入活动诱发了讷木尔河深大断裂所致。 相似文献
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用数字记录资料测定腾冲火山区的微震参数 总被引:6,自引:3,他引:3
利用数字化地震记录资料 ,测定了腾冲火山及其周围地区的地震基本参数 ,结果表明 ,腾冲火山区内的地震活动以微震为主 ,震级多数在 1~ 2 5级之间 ,且地震活动频度低 ;而周围地区的构造地震活动频繁 ,且强度大。在腾冲火山区内地震活动的空间分布也表现出明显的非均匀性 ,以腾冲县城以北 (即 2 5°N以北 )的火山区内地震活动少 ,而县城以南的火山区 (热海热田地区 )微震活动相对多 ,且以微震群的形式发生。根据C F Richter震级标度测定的震级结果 ,火山区的微震活动事件可达 0 4震级单位。震源深度的定位结果给出 ,火山地区的微震震源深度绝大多数在 1~ 6km的范围 ,属于典型的浅源地震 ,而周围地区构造地震的震源深度多多数大于 2 0km。腾冲火山区的微震活动分布、地震强度、及震源深度特征所表现的现象可能与地下岩浆体活动相关 ,显示了与火山热物质孕震机理有关的明显特征。 相似文献
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腾冲火山区地震构造应力场研究 总被引:5,自引:2,他引:3
通过对腾冲火山区强震和中小地震震源机制制解分析,对火山区构造应力场方向空间分布,以及震源类型和破裂特征作了研究。利用腾冲火山区中小地震地震波资料,计算得到的地震震源处剪应力强度值,对火山区应力场强度或初始应力状态进行了研究。腾冲火山区构造庆力场主要为北北东-北东-北东东向,接近水平的压应力场。腾冲火山区凛环境剪应力场高值区所包围的低剪应力值分布区。腾冲火山区地震震源具有多种类型,震源破裂具有多种形 相似文献
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第四纪火山区活动构造的识别和地震危险性评价 总被引:3,自引:0,他引:3
在第四纪火山区作活动构造研究时需要仔细地区分岩浆原生构造,火山区非构造变动和真正的活动断裂。第四纪火山区晚更新世晚期以来不再活动的断裂不宜看成危险性断裂。第四纪火山可能发生中强地震,极少可能发生大地震。 相似文献
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本文选择五大连池火山区微震活动的模拟、数字地震记录,研究地震波特征,对火 山构造地震进行地震波型分类,分析地震波动力学、运动学特性,以期对我省五大连池火山 区构造地震波有一个初步认识. 相似文献
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五大连池火山区尾波Q值研究 总被引:1,自引:1,他引:0
选取五大连池火山地区2008年至2011年ML>0.6火山地震事件39个,根据尾波散射理论,利用Sato模型计算其尾波Q值,获得整个火山区尾波Q与频率f关系Q(f)=(34.89±8.75)f1.0727±0.2253,表现为低Q高η值的火山构造活动活跃区域尾波特征,同时获得老黑山、火烧山附近区域尾波Q0值为20.60,与国内外火山区尾波Q值加以对比,对本区域地震活动性进行分析,并结合本区其他火山研究成果给予简单解释. 相似文献
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应用双差定位法对吉林区域中小地震及乾安-前郭5.0级地震余震的重新定位 总被引:1,自引:0,他引:1
本文利用双差定位法对发生在吉林区域317次中小地震进行重新定位,得到265次地震定位结果,显示震中分布总体格局变化不大,但局部地区地震有向构造带及其交汇处集中的变化,震群分布更加集中,震源深度主要集中在0~25km。对乾安—前郭M5.0级地震余震序列双差定位,结果显示地震更加集中于极震区,方向呈北偏东,深度分布在10KM左右。研究结果初步表明该方法定位精度比较高,无论在残差、测定误差、震中分布还是震源深度方面,都比原来定位结果有较大改进。 相似文献
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利用四川数字地震台网和流动地震台站在芦山MS7.0地震震后(2013年4月20日—6月23日)记录到的2026次区域地震事件的28188条P波到时资料,采用地震层析成像方法反演得到了芦山地震震源区及其周边区域中上地壳P波三维速度结构. 结果表明,浅部地壳的P波速度异常分布特征与地表地质构造、 地形和岩性密切相关,即成都断陷盆地表现出与第四纪沉积有关的低速异常区;犍为、 乐山一带的川中微升区和川青块体龙门山以西的邻近地带均表现为与构造抬升有关的高速异常;宝兴、 康定附近分布的基性火山岩及火山碎屑岩均呈局部高速异常分布. 芦山地震震源位于高低速异常分界线附近且偏向高速体一侧,其下方存在明显的低速异常分布,可能与流体的存在有关. 流体的作用导致中上地壳内部发震层的弱化,使孕震断层易于破裂,可能对芦山地震起到了触发作用. 芦山地震与汶川地震两次地震的余震密集区相距50 km,这50 km地震空区震源体的深度范围附近目前正处于高速异常区内,加之龙门山断裂带西南段又具有比较典型的断错地貌发育,使得该段地震空区(大邑—邛崃活动断裂破裂空段)现在所处的深浅部构造环境变得复杂,其潜在的地震危险性仍值得进一步关注. 相似文献
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利用双差定位法对瀑布沟水库及邻区1 834次小震进行了重新定位,并对距水库水域最近的2个小震集中区的地震性质进行了分析。重新定位后得到1 708次小震结果,定位残差由原来的0.93s降为0.21s,水平向估算误差平均为0.6km,垂直向估算误差平均为2.9km; 平面空间分布显示,重新定位地震主要分布在研究区的西南(A区)、库中区(C区)和水库大坝附近(D区); A区小震密集与其处于鲜水河断裂中南段、安宁河北段和大凉山断裂北段交会区的特殊地理位置有关。C,D区高度集中分布的小震与水库蓄水无关,属于各种建设施工造成的爆破地震。 相似文献
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渤海地震活动特征 总被引:32,自引:0,他引:32
渤海是我国东部陆缘海湾地震活动性最高的地区。研究渤海的地震活动特征,对探讨我国沿海地震的成因、沿海现代地质构造活动性质以及海洋石油开发都有一定意义。本文研究了渤海的历史地震资料,除中国大地震目录已发表的地震外,本文新增补了2次6—61/2级地震和3次5级左右地震。讨论了1969年渤海大地震的震源深度,大地震目录给出的深度为35公里(位于地壳以下)。根据其他作者的最新测定的结果和作者等人重新测定的微震震源深度,认为1969年渤海大地震的震源深度为25公里较合适,渤海地震都位于地壳以内。渤海地震活动的时间分布与华北地震区完全一致,渤海地震是华北地震区的一部分。渤海内部的现代构造运动是以水平构造应力场作用下的走滑运动为主要特征。渤海地震活动与北北东向的郯庐断裂的右旋走滑活动以及与其共轭的北西西断裂的左旋走滑活动有关。 相似文献
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THE SOURCE PARAMETERS AND RUPTURE PROCESS OF THE MW7.0 EARTHQUAKE IN ALASKA,USA ON DECEMBER 1, 2018 
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下载免费PDF全文 XU Zhi-guo ZHANG Huai ZHOU Yuan-ze LIANG Shan-shan SU Zhe SHI Jian-yu ZHAO-Bo 《地震地质》2019,41(5):1223-1238
A magnitude MW7.0 earthquake struck north of Anchorage, Alaska, USA on 1 December 2018. This earthquake occurred in the Alaska-Aleutian subduction zone, on a fault within the subducting Pacific slab rather than on the shallower boundary between the Pacific and North American plates. In order to better understand the earthquake source characteristics and slip distribution of source rupture process as well as to explore the effect of tectonic environment on dynamic triggering of earthquake, the faulting geometry, slip distribution, seismic moment, source time function are estimated from broadband waveforms downloaded from IRIS Data Management Center. We use the regional broadband waveforms to infer the source parameters with ISOLA package and the teleseismic body wave recorded by stations of the Global Seismic Network is employed to conduct slip distribution inversion with iterative deconvolution method. The focal mechanism solution indicates that the Alaska earthquake occurred as the result of tensile-type normal faulting, the estimated centroid depth from waveform inversion shows that the earthquake occurred at the depth of 56.5km, and the centroid location is 10km far away in northeast direction relative to the location of initial epicenter. We use the aftershock distribution to constrain the fault-plane strike of a normal fault to set up the finite fault model, the finite fault inversion shows that the earthquake slip distribution is concentrated mainly on a rectangular area with 30km×20km, and the maximum slip is up to 3.6m. In addition, the slip distribution shows an asymmetrical distribution and the range of possible rupture direction, the direction of rupture extends to the northeast direction, which is same as that of aftershock distribution for a period of ten days after the mainshock. It is interesting to note that a seismic gap appears in the southwest of the seismogenic fault, we initially determined that the earthquake was a typical normal fault-type earthquake that occurred in the back-arc extensional environment of the subduction collision zone between the Pacific plate and the North American plate, this earthquake was not related to tectonic movement of faults near the Earth's surface. Due to the influence of high temperature and pressure during the subduction of the Pacific plate toward to the north, the subduction angle of the Pacific plate becomes steep, causing consequently the backward bending deformation, thus forming to a tensile environment at the trailing edge of the collision zone and generating the MW7.0 earthquake in Alaska. 相似文献
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Motoo Ukawa 《Bulletin of Volcanology》2005,68(1):47-56
Beneath Mount Fuji, the highest active volcano in Japan, deep low-frequency (DLF) earthquake activity has been monitored since the early 1980s. The DLF earthquakes occurred in the mid-crustal depth range, and burst-type activity lasting from several minutes to 30 min was detected 10 to 20 times in an ordinary year. The DLF earthquake activity increased sharply in the period from October 2000 to May 2001, showing swarm-like activity. The occurrence rate during the DLF earthquake swarm was approximately 20 times higher than the usual activity, and the wave energy released during the swarm period was twice as high as the total wave energy during the past 20 years. The DLF earthquakes in the period from 1987 to 2001 were relocated by estimating station corrections in order to reduce the effect of the change of seismic station distribution. The epicenters of most DLF earthquakes occurred in an elongated region with a long axis of about 5 km, whose center is located 2–3 km NE from the summit. A few percent of the DLF earthquakes, however, occurred around the summit area, significantly apart from the main epicenter region. The focal depths of well-located DLF events range from 10 to 20 km. During the high activity period in 2000 and 2001, most DLF events occurred within this main hypocenter area. The sharp increase of DLF earthquake activity at Mount Fuji started immediately after magma discharge and intrusion events in the Miyake-jima and Kozu-shima regions in July and August 2000. The tectonic and volcanic activity changes around the area suggest that the DLF earthquake swarm at Mount Fuji was triggered by the change of state of the deep magmatic system around Mount Fuji.Editorial responsibility: J Stix 相似文献
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On July 31th, 2016, a magnitude 5.4 earthquake struck Cangwu Country, Guangxi Zhuang Autonomous Region, it was the largest earthquake recorded by Guangxi Seismological Network since it set up. The number of people affected by the earthquake had reached 20 000, and the direct economic losses caused by the earthquake were nearly 100 million Yuan.
After the earthquake, USGS provided a global earthquake catalog showing that the focal depth of Cangwu earthquake was about 24.5km. However, the result given by the Global Centroid Moment Tensor showed the focal depth of this earthquake was 15.6km. However, the result obtained by Xu Xiaofeng et al. using CAP method was 5.1km. It was clear that the focal depths of Cangwu earthquake given by different institutions were quite different from each other. However, accurate focal depth of the earthquake has important significance for exploring the tectonic mechanism near the epicenter, so it is necessary to further determine the more accurate depth of the Cangwu earthquake.
In order to further accurately determine the focal depth of Cangwu earthquake, we used the global search method for travel-time residual to calculate the focal depth of this earthquake and its error range, based on the regional velocity model, which is a one-dimensional velocity model of the Xianggui tectonic belt produced by the comprehensive geophysical profile. Then, we inverted the focal mechanism of this earthquake with the CAP method. Based on this, the focal depth of Cangwu MS5.4 earthquake was further determined by the method of the Rayleigh surface wave amplitude spectrum and the sPL phase, respectively.
Computed results reveal that the focal depth of this earthquake and its error range from the travel-time residual global search method is about(13±3)km, the focal depth inverted by CAP method is about 10km, the focal depth from sPL phase is about 10km, and the focal depth from Rayleigh surface wave amplitude spectrum is about 9~10km. Finally, we confirmed that the focal depth of Cangwu MS5.4 earthquake is about 10km, which indicates that this earthquake still occurred in the upper crust. In the case of low network density, the sPL phase and Rayleigh wave amplitude spectrum recorded by only 1 or 2 broadband stations could be used to obtain more accurate focal depth.
The focal depth's accuracy of Cangwu MS5.4 earthquake in the USGS global earthquake catalog has yet to be improved. In the future, we should consider the error of the source parameters when using the USGS global earthquake catalog for other related research. 相似文献
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The paper introduces the tectonic background,focal mechanism and distribution of aftershock of the Wenchuan earthquake on May 12,2008. The earthquake is considered to be the result of long-term interaction between the eastward movement of the Bayan Har Block and the Sichuan Basin. Most of the earthquake energy was released in an area (the seismic source body) 330km long,52km wide and 20km deep over 100s. Energy release in the source body was extremely uneven,and strong ground motion in the epicenter area shows obvious asymmetrical character in the time and space scale. The high-intensity area is distributed along the source body,and the intensity distribution bears an obvious anomalous characteristic. The investigation results indicate that more than 90 percent of casualties caused by this earthquake were in the areas of intensity IX or above. Houses,schools and hospitals etc. suffered serious damage. Lifelines such as transportation,water conservation etc. also suffered significant damage. Besides,earthquake-triggered avalanches,landslides,mud-rock flows and so on were extremely serious. The tremendous earthquake disaster highlighted the deficiencies in disaster prevention and mitigation management,scientific earthquake research,technology and application of earthquake disaster prevention,and publicity of earthquake preparedness and disaster reduction. 相似文献