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汶川MS8.0大地震在远离震中近200 km的汉源县县城产生了高烈度异常, 其原因比较复杂.为了分析土层结构对汶川大地震中汉源县老县城高烈度异常的影响, 在汉源县城震害科学考察基础上, 依据地震烈度异常的分布情况, 在背后山滑坡前缘地带布设5个工程地质勘察钻孔, 获得了汉源县老县城场地土层结构资料.在现场测试和室内试验的基础上, 给出了汉源县老县城场地各层土体动力学参数.本文利用汶川地震九襄强震台的强震记录, 结合其台站的场地资料反演给出了汉源县老县城的基岩地震动时程, 作为地震反应分析的基岩输入地震动.在此基础上利用土层地震反应一维等效线性方法对汉源县老县城场地进行了地震反应分析, 并将计算所得结果与Ⅵ度区其它强震台站获得的强震记录进行比较.研究结果表明, 汉源县老县城土层结构对地震动的放大作用导致地表地震动异常, 是汉源县老县城高烈度异常的主要原因之一. 相似文献
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汶川特大地震汉源烈度异常原因的初步分析 总被引:7,自引:1,他引:6
远离震中的汉源县老县城在汶川大地震中遭到了严重震害,是Ⅵ度区内的唯一的Ⅷ度烈度异常区.汉源的地震烈度异常现象引起学术界的广泛关注.在汉源科学考察基础上,介绍了汉源震害情况,收集和整理了汉源县城及附近有关工程场地的强震和土体力学参数资料.通过背后山滑坡体有限元分析结果与汉源附近强震台记录的比较,从传递函数角度分析了背后山滑坡复活对烈度异常的影响,研究了汉源特殊土层结构对地震动的影响.结果表明,背后山滑坡的复活和特殊土层结构的放大作用等场地条件的影响是引起烈度异常的主要原因.所得结论对进一步分析汉源烈度异常的原因具有一定的参考价值. 相似文献
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团树断层场地在多次地震中出现了烈度异常。为了弄清烈度异常的原因,应用显式有限元方法,数值模拟了在脉冲地震波斜入射情形下断层场地的地震反应。结果表明:在基岩山脚附近土层场地地震动放大比基岩山区平均高4倍、比远离基岩山脚土层场地平均高2倍,与历史震害分布有较好的对应。 相似文献
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在历次地震中,地形、地貌及场地条件复杂的山区容易出现房屋建筑震害异常情况。分析震害异常的原因,对于进行建筑抗震设防以减少地震灾害损失具有重要意义。本文主要对2014年盈江524、530两次地震后Ⅷ度区的卡场镇麻竹岭岗房屋破坏及场地条件情况进行调查,根据麻竹岭岗的地形条件由高到低分为3个区,对3个区内的建筑破坏情况进行分析比较,表明震害程度呈现出明显的从山底至山顶逐渐加大的趋势,揭示出显著的山体影响作用。重点对山顶的穿斗木结构破坏情况进行了分析,找出了造成建筑结构破坏的几个不利因素,包括山丘地形顶部放大效应、覆盖土层放大效应以及多次地震震害累积效应。 相似文献
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地下管道的震害预测方法简述 总被引:1,自引:0,他引:1
强烈的地面运动或场地失效等因素是造成地震中地下管道破坏的主要因素。本文对地震波作用下和砂土液化条件下管道的震害预测方法进行了概述,并基于综合概率法对埋地管道进行了分析预测。 相似文献
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“5·12”汶川8.0级地震汉源烈度异常机理的初步探讨 总被引:8,自引:0,他引:8
本文通过总结分析汉源烈度异常主要特征,初步分析了导致烈度异常的可能原因。初步研究结果表明,“5·12”汶川8.0级地震震源过程及其能量释放空间分布和场地条件是导致汉源烈度异常的主要因素,同时莫霍界面反射波S11断层破裂带的阻震及激震效应等,也可能是汉源烈度的影响因素。探索汉源烈度异常对总结特大地震烈度分布、震害特征和成灾机理具有重要意义。为此作者提出,应在震害特征总结提炼的基础上,考虑震源机制、地壳介质、场地非线性等因素,对汉源烈度异常区进行全面的数值模拟,进一步确定汉源地震烈度异常的机理。 相似文献
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通过对汶川地震、通海地震、唐山地震和澜沧-耿马地震中水利工程破坏情况的统计分析,本文以统计表的形式直观地反映了水利工程震害的特点及破坏形式.根据水利工程的震害特点,探讨分析了水利工程震害的主要影响因素,结果表明地震烈度、结构设计、施工质量、地基及场地条件是水利工程震害的主要影响因素.基于水利工程震害的特点及主要影响因素... 相似文献
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根据九寨沟Ms 7.0地震现场调查结果,总结了甘肃文县低烈度区震害的一般特征,分析了低烈度区烈度异常点的震害特点,并对产生烈度异常的原因进行了探讨。调查和分析研究结果表明:由于研究区的建筑多在汶川Ms 8.0大地震后进行了重建或抗震加固,且地震持时较短,此次地震中低烈度区房屋震害总体较轻。然而,低烈度区存在建筑裂缝、滑坡、滑塌和桥梁损坏等显著的烈度异常现象,其主要原因是建筑场地位于滑坡体以及高陡边坡等抗震不利地带;此外,地震波的传播方向和研究区内岩土体的特性也是造成低烈度区烈度异常的重要因素。地震地质灾害需在地震烈度评定标准修订时予以重点考虑。 相似文献
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本文通过地震史料考证,野外地质调查,钻孔土层力学性质分析,场地震害考察等资料的研究,认为琼州历史地震在滨海地带第四纪软弱土层中诱发了砂土液化、软土流滑、造成地基失效、场地不均匀沉陷的情况,是导致震区内特殊地段“陆地沉陷”的主要原因 相似文献
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On April 20, 2013, an earthquake with mag- nitude 7.0 occurred in the southwest of the Longmenshan fault system in and around Lushan County, Sichuan Province, China. This devastating earthquake killed hun- dreds of people, injured 10 thousand others, and collapsed countless buildings. In order to analyze the potential risk of this big earthquake, we calculate the co- and post-seismic surface deformation and gravity changes of this event. In this work, a multilayered crustal model is designed, and the elastic dislocation theory is utilized to calculate the co- and post-seismic deformations and gravity changes. During the process, a rupture model obtained by seismic waveform inversion (Liu et al. Sci China Earth Sci 56(7): 1187-1192, 2013) is applied. The time-dependent relaxation results show that the influences on Lushan and its surrounding areas caused by the Ms7.0 Lushan earthquake will last as long as 10 years. The maximum horizontal displacement, vertical uplift, and settlement are about 5 cm, 21.24 cm, and 0.16 m, respectively; the maximal positive and nega- tive values of gravity changes are 45 and -0.47 μGal, respectively. These results may be applied to evaluate the long-term potential risk caused by this earthquake and to provide necessary information for post-earthquake reconstruction. 相似文献
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In this study, we determined fnax from near- field accelerograms of the Lushan earthquake of April 20, 2013 through spectra analysis. The result shows that the values of fmax derived from five different seismography stations are very close though these stations roughly span about 100 km along the strike. This implies that the cause offmax is mainly the seismic source process rather than the site effect. Moreover, according to the source-cause model of Papageorgiou and Aki (Bull Seism Soc Am 73:693-722, 1983), we infer that the cohesive zone width of the rupture of the Lushan earthquake is about 204 with an uncertainty of 13 m. We also find that there is a significant bulge between 30 and 45 Hz in the amplitude spectra of accel- erograms of stations 51YAL and 51QLY, and we confirm that it is due to seismic waves' reverberation of the sedi- mentary soil layer beneath these stations. 相似文献
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The earthquake occurred in Lushan County on 20 April, 2013 caused heavy casualty and economic loss. In order to understand how the seismic energy propagates during this earthquake and how it causes the seismic haz- ard, we simulated the strong ground motions from a rep- resentative kinematic source model by Zhang et al. (Chin J Geophys 56(4):1408-1411, 2013) for this earthquake. To include the topographic effects, we used the curved grids finite difference method by Zhang and Chen (Geophys J Int 167(1):337-353, 2006), Zhang et al. (Geophys J Int 190(1):358-378, 2012) to implement the simulations. Our results indicated that the majority of seismic energy con- centrated in the epicentral area and the vicinal Sichuan Basin, causing the XI and VII degree intensity. Due to the strong topographic effects of the mountain, the seismic intensity in the border area across the northeastern of Boxing County to the Lushan County also reached IX degree. Moreover, the strong influence of topography caused the amplifications of ground shaking at the moun- tain ridge, which is easy to cause landslides. These results are quite similar to those observed in the Wenchuan earthquake of 2008 occurred also in a strong topographic mountain area. 相似文献
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Using the results of aftershock relocation, inversion on seismic waves and InSAR results, and surface rupture displacements obtained by geological survey after the earthquake, this paper constructs a fault model of the Yushu Ms7. 1 earthquake. Based on rectangular dislocation theory in an elastic-viscoelastic layered medium, we have simulated the co- seismic deformation and gravity change with gravitational effect considered. The pictures show that the absolute gravity measuring point is beside the extremum of coseismic gravity change, and the numerical value reaches 25.02 x 10-Sm. s-2. After a discussion about the gravity changes before the earthquake and the coherence consistency between two FG-5 absolute gravimeters, we think that the measured value 27.2 × 10^-8 m· s^-2 at Yushu station is coseismic gravity change. It's coincident with the simulation results based on dislocation theory. Therefore it is a good tool to test the near-field changes found by dislocation theory. 相似文献
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1调查经过1933年8月25日大约在下午2时半,四川茂县之北叠溪,忽然发生大地震,即时间附近群山崩倒,叠溪城全部毁灭,岷江断流。叠溪周围30里内,属于强烈地震区,在这一范围内,任何房屋庐舍,全部破坏,群山崖壁,全部崩坍。在叠溪圆径百里之内,所有道路都被破坏,不能通行。邮电线路,全部不通。当时只知茂汶 相似文献
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Centroid depth of earthquakes is essential for seismic hazard mitigation. But, various studies provided different solutions for the centroid depth of the damaging 2013 Lushan earthquake, thus hindering further studies of the earthquake processes. To resolve its centroid depth and assess the uncertainties, we apply the teleseismic cut and paste method to invert for centroid depth with teleseismic body waves in the epicentral distance of 300-90~. We performed the inversion for P waves only as well the case of both P and SH waves and found that both cases lead to depth solutions with difference less than 0.5 km. We also investigated the effects on depth inversion from azimuth gap of seismic stations, source duration, and comer fre- quency of filter. These various tests show that even azi- muthal distribution of seismic stations is helpful for accurate depth inversion. It is also found that estimate of centroid depth is sensitive to source duration. Moreover, the depth is biased to larger values when corner frequency of low-pass filter is very low. The uncertainty in the velocity model can also generate some error in the depth estimation (- 1.0 km).With all the above factors consid- ered, the centroid depth of Lushan earthquake is proposed to be around 12 km, with uncertainty about 2 km. 相似文献
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We process the standard 30 s, static GPS data and the 1 s, high-rate GPS (HRGPS) data provided by the Crustal Movement Observation Network of China with GAMIT/GLOBK software package, and obtain the co- seismic displacements of near field and far field, and the epoch-by-epoch time series of HRGPS during Lushan earthquake. GPS data from about 20 sites in Sichuan province, which located between 40 and 450 km from the epicenter, are analyzed so as to study the characteristics of the static displacements and the dynamic crustal defor- mations, with periods ranging from several minutes to over a month. The result shows that: the static displacements caused by Lushan earthquake are limited to several centi- meters; the nearest station SCTQ at 43 km from the epi- center has the largest static displacement of about 2 cm, while the other stations generally have insignificant dis- placements of less than 5 mm. the stations in the east ofSichuan-Yunnan region shifts 5-10 mm toward the southwest, and the stations in the middle-west of Sichuan Basin moves indistinctively 1-2 mm toward the northwest; station SCTQ has the largest kinematic displacement of about 4 and 3 cm peak-to-peak on the north and east component, respectively, and is much greater than the static permanent displacement; for the stations located at a distance greater than 150 km from the epicenter, the kinematic motions are generally insignificant; exception- ally, station SCNC and station SCSN in central Sichuan Basin have significant kinematic motions although they are more than 200 km away from the epicenter. 相似文献
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Monitoring of subsurface fluid (underground fluid) is an important part of efforts for earthquake prediction in China. The nationwide network, which monitors groundwater level, water temperature, and radon and mercury in groundwater, has been constructed in the last decades. Large amounts of abnormal fluid changes before and after major earthquakes have been recorded, providing precious data for research in earthquake sciences. Many studies have been done in earthquake fluid hydrogeology in order to probe the nature of the earthquake. Much progress in earthquake fluid hydrogeology has been made in the last decades. The paper provides a review of the advances in research on earthquake fluid hydrogeology over the last 40 years in China. It deals with the following five aspects: (1) an introduction to the development history of monitoring networks construction; (2) cases of different subsurface fluid changes recorded before some major earthquakes which occurred in the last decades; (3) characteristics of subsurface fluid changes following major earthquakes; (4) mechanism of subsurface fluid changes before and following earthquakes; (5) application of earthquake fluids in the hydrogeology field. 相似文献
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The dense broadband seismic network provides more high-quality waveform that is helpful to improve constraint focal depth of shallow earthquake. Many shallow earthquakes occurring in sediment were regarded as induced events. In Sichuan basin, gas industry and salt mining are dependent on fluid injection technique that triggers microseismicity. We adopted waveform inversion method with regional records to obtain focal mechanism of an Ms 4.8 earthquake at Changning. The result suggested that the Changning earthquake occurred at a ESE thrust fault, and its focal depth was about 3 km. The depth phases including teleseismic pP phase and regional sPL phase shows that the focal depth is about 2 km. The strong, shortperiod surface wave suggests that this event is a very shallow earthquake. The amplitude ratio between Rayleigh wave and direct S wave was also used to estimate the source depth of the mainshock. The focal depth(2–4 km) is far less than the depth of the sedimentary layer thickness(6–8 km) in epicentral region. It is close to the depth of fluid injection of salt mining, which may imply that this event was triggered by the industrial activity. 相似文献