共查询到17条相似文献,搜索用时 93 毫秒
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通过对2001年昆仑山口西8.1级地震区冻土震害考察研究表明,震区主要存在冰碛、冲积、洪积和湖积等成因的冻土,沿地震破裂带冻土厚度变化较大。震区冻土变形破坏主要包括地震构造成因的地震破裂带和由地震振动引起的裂缝、液化、震陷和崩塌等。冻土中地震破裂带在地表主要以脆性变形为主,在地震断裂左旋走滑运动作用下,主要由剪切裂缝、张裂缝和开裂的挤压鼓包等组成。裂缝、液化、震陷和崩塌等变形破坏的展布特征及其组合形式与震区岩土与环境条件密切相关;本次地震震害具有地震破裂带规模大、有建筑物分布的青藏公路一线地震烈度衰减较快和震害分布受岩土条件影响大等特点。 相似文献
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2008年5月12日汶川MS8.0地震的震中烈度为Ⅺ度,但位于地震烈度为Ⅹ度区边缘的绵竹县汉旺镇,无论是房屋毁坏情况还是遇难和失踪人员的数目,均高出周边地震烈度Ⅰ度,接近极震区的破坏程度。文中从汉旺镇周边地表地震破裂带展布方式的角度讨论了这种震害加重现象的原因,介绍了位于汉旺镇北面和南面出现的2条相距1.5km呈左阶斜列展布的地表破裂带。其中,位于汉旺镇北侧的地表破裂带,垂直位移1.4m,水平右旋位移0.44m;位于汉旺镇南侧的地表破裂带,垂直位移量由西向东递减,为3.0~0.2m。尽管这2条地表破裂带没有从汉旺镇中心通过,但汉旺镇正位于这2条地表破裂带夹持的左阶阶区,致使阶区内建筑物除遭受来自震源的振动外,又受到阶区内的挤压,由此加重了汉旺镇建筑物的破坏,也显示出地表破裂带对建筑物破坏形式的多样性。汉旺镇汶川MS8.0地震震害实例表明,地表破裂带的阶区,也是遭受地震时破坏加重的特殊构造部位 相似文献
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通过对2022年1月8日青海门源6.9级地震的震源机制、发震构造、房屋和重大生命线工程震害、地震地表破裂带等震害调查资料的综合分析,系统介绍了此次地震震源机制、发震构造、地震烈度分布特点、房屋破坏特征及机理、生命线工程破坏特征及地表破裂带特征。研究结果表明:门源6.9级地震震中位置位于冷龙岭断裂带的西段,性质以左旋走滑为主,其与震源机制解得到的结果相一致,均为走滑型破裂类型;地震最大烈度Ⅸ度,烈度Ⅵ度(含)以上面积约23 417 km2,等震线长轴呈NWW走向,长轴200 km,短轴153 km;整体上房屋破坏较轻,甘肃境内主要属Ⅶ和Ⅵ度区影响范围,极少部分为Ⅷ度区影响范围;此次地震中滑坡灾害和生命线工程震害较少,主要在Ⅸ和Ⅷ度区造成部分路面裂缝,最为严重的则为兰新高铁浩门至军马场区间祁连山一号隧道群线路桥梁严重受损,隧道震害主要集中在断层影响范围内,其中隧道受破坏严重段约350m,占隧道全长的5.33%,受破坏较严重段分别位于严重段大里程侧402m和小里程侧646m范围内,占隧道全长的15.96%,其余段落震害总体轻微;地震造成地表破裂带约22 km,地震造成的... 相似文献
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尼泊尔8.1级地震建筑物震害遥感提取与分析 总被引:2,自引:2,他引:0
2015年4月25日尼泊尔发生的8.1级地震,造成重大人员伤亡与经济损失。在地震前、后灾区高分遥感影像分析处理基础上,结合现场实地调查,对灾区房屋建筑及其震害程度进行了遥感解译,编制了地震灾区房屋建筑震害分布图。结果分析表明:尼泊尔地震灾区影像上显示的建筑物震害分布与该区域房屋结构类型、主余震位置和区域活动构造分布密切相关。其中,房屋较为严重倒塌区域主要分布在8.1级主震和7.5级余震震中附近,但这两个区域并没有相连;居民点建筑物个别倒塌的居民地则连成一个区域。影像上显示的建筑物倒塌区域,与多数8级巨大地震比较,总体上极震区震害偏轻,但在南南西(垂直于破裂方向)上展布较宽。这一特征与引发该地震的印度与欧亚大陆板块边缘活动断裂在深部呈近似于平行地表的低角度断层面破裂引起的地震动能量在地表相对较宽而低的分布特征是一致的。 相似文献
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青海玉树M_S7.1级地震地表破裂带的遥感影像解译 总被引:1,自引:1,他引:0
2010年4月14日青海省玉树发生MS7.1级地震,造成严重的人员伤亡和重大的经济损失。除组织现场快速震害评估和地表破裂带调查外,利用高分辨率卫星影像解译是迅速给出初步震害评估和同震地表破裂的位置和展布的最佳途径。本文通过对震前、震后高分辨率SPOT卫星影像的对比,解译出了12km长的同震地表破裂带,其在影像上主要表现为线性阴影和色彩变化。地表破裂带位置和先存的断层、老破裂带位置一致,说明青海玉树地震属于原地复发型地震。同时,解译结果也得到了来自野外实地调查结果的验证,证明了遥感解译的可信性和及时性。但解译破裂长度远小于实际破裂长度,也说明了基于2.5m分辨率的SPOT卫星影像的遥感解译存在较大的局限性。 相似文献
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玉树地震地表破裂对建筑物影响的分析 总被引:1,自引:0,他引:1
本文首先以玉树县结古镇、隆宝镇沿破裂带追索等调查资料为例,详细介绍了该地区地震破裂带附近的典型建(构)筑物灾害事例,然后结合既往有关的科研成果和关于汶川地震地表破裂的研究成果,根据地表破裂的特征和建(构)筑物震害性质,对考察现象进行了分析和讨论,探索提出了玉树地震地表破裂宽度和建(构)筑物震害指数的相关性和基本特点,为今后该地区的抗震防灾提供参考。 相似文献
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2008年5月12日汶川8.0级地震在北川县城造成了巨大的破坏,导致上万人死亡,整个北川县城变为废墟。现场地震科考分析显示,造成北川县城建筑物和道路严重损毁以及人员重大伤亡的三个主要原因为:活断层错动产生的地表破裂效应,地震引发的次生地质灾害(崩塌、滑坡)和强地震动产生的振动破坏效应。北川县城主断裂和次级断裂沿线分布的建筑物震害较重,而邻近断裂的建筑物震害相对较轻;地震触发的王家岩滑坡和景家山崩塌对北川县城造成了极大的破坏,导致2000余人死亡;而振动破坏效应在北川县城普遍存在,它产生的水平剪切运动对建筑物的危害很严重。 相似文献
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2022年1月8日,青海省海北藏族自治州门源县发生MS6.9地震,震中位于青藏高原东北缘地区祁连—海原断裂带的冷龙岭断裂和托勒山断裂构造转换区域(37.77°N,101.26°E)。震后野外现场考察结果表明,此次地震形成的同震地表破裂带总长度约为26 km,整体走向NWW向,破裂性质以左旋走滑局部逆冲为主。断层错动造成的破坏形式以雁列式组合的张裂隙、张剪裂隙、挤压鼓包、断层陡坎等为主。其中,道河至硫磺沟段地表破裂最为强烈,规模大且连续性好,造成的震害最为显著,地表破裂规模向东、西两端逐渐衰减。破裂带穿过区域内多条河流,造成显著的冰面破裂变形,并沿河岸形成一系列的边坡崩塌、滚石等地质灾害。综合破裂带及震害规模分析,宏观震中位于道河至硫磺沟地区。 相似文献
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汶川M_S 8.0地震断层与地震灾害初步分析 总被引:6,自引:0,他引:6
对于特大地震近断层地震场的空间分布的复杂性学术界一直很关注,由于样本地震数量和资料的不足,至今还没有非常清晰的结论。通过参加汶川MS8.0地震的应急科学考察,对震中区和高烈度区断层破裂带附近的地震灾害情况进行了现场调查。文中以典型事例为主线介绍了现场考察的结果,结合既往的研究成果和汶川地震的震源特性,分析讨论了地表破裂带、地震动以及建筑物震害之间的关系。结果表明:1)地震断层发生强变形和地表破裂对建筑物的损害现象非常明显,对具有大震级发震危险的断裂带,今后应该考虑进行一定宽度的破裂避让或采取针对性的必要措施。2)初步探讨了紧邻断裂带的建筑物没有倒塌的可能机理,第一,出现地表破裂的大部分区域为基岩或坚硬的场地,场地条件相对较好;第二,存在导致地表破裂的浅部有效应力降和破裂速率相对较低,导致了1s附近的地震动相对低下的可能性 相似文献
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Living with disaster is an objective reality that human must face especially in China. A large number of earthquake case studies, such as the 2008 Wenchuan earthquake, 2010 Yushu earthquake, 2014 Ludian earthquake, have demonstrated that earthquake heavy damage and casualties stem from ground-faulting or rupturing along seismogenic active fault, near-fault high ground accelerations and building catastrophic structural failure. Accordingly, avoidance of active faults may be an important measure to effectively reduce earthquake hazard, which may encounter in the future, but how to avoid an active fault and how much a setback distance from the active fault is required to ensure that the ground faulting and rupturing has no any direct impact on buildings. This has been the focus of debate both for domestic and foreign scholars. This paper, first of all, introduces the definition of active fault. Then, quantitative analyses are done of the high localization of earthquake surface ruptures and relationship between the localized feature of the coseismic surface ruptures and building damages associated with the measured widths of the historical earthquake surface rupture zones, and an average sstatistic width is obtained to be 30m both for the earthquake surface rupture zones and heavy damage zones along the seismogenic fault. Besides, the widths of the surface rupture zones and spatial distribution of the building damages of the 1999 Chi-Chi earthquake and 2008 Wenchuan earthquake have also been analyzed to reveal a hanging-wall effect:Width of surface rupture zone or building damage zone on the hanging-wall is 2 or 3 times wider than that on its foot-wall for a dip-slip fault. Based on these latest knowledge learnt above, issues on avoidance object, minimum setback distance, location requirement of active fault for avoidance, and anti-faulting design for buildings in the surface rupture zone are further discussed. Finally, we call for national and local legislatures to accelerate the legislation for active fault survey and avoidance to normalize fault hazard zoning for general land-use planning and building construction. This preventive measure is significantly important to improve our capability of earthquake disaster reduction. 相似文献
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龙首山断裂带位于青藏高原向北东推挤的最前缘,是河西走廊与阿拉善地块之间的分界断裂之一.虽然观测精度有限,1954年发生在该断裂带上的71/4级地震是该断裂上少有的有现代地震观测和记录的大地震.本次地震仅在龙首山北缘断裂带两个次级断裂段之间的一条转换断层上形成了长7 km左右的连续地震地表破裂带,以北西向右旋兼正断为主要特征,这与区域上近东西向左旋逆断构造运动特征差异较大.经过多次野外调查和地质填图,发现在主断层上没有形成地震地表破裂带,而地震震害的分布又完全受龙首山南北两条断裂所围限,说明地震的孕震可能与龙首山断裂带主断裂有关,转换断层上的地表破裂仅为局部的应力释放.利用震源机制解资料,通过静态库仑应力变化模拟可以看到,如果主震发生在南缘断裂上,对地表破裂有显著的触发作用.综合考虑北缘断层可能存在的动态触发作用,说明目前所见地表破裂是龙首山断裂带主断裂地震的同震响应.小震精定位也显示,龙首山南北两侧的断裂在约10 km范围内形成一狭窄的倒三角形,并有向北扩展的趋势. 相似文献
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Jing Liu-Zeng Wenqian Yao Xiaoli Liu Yanxiu Shao Wenxin Wang Longfei Han Yan Wang Xianyang Zeng Jinyang Li Zijun Wang Zhijun Liu Hongwei Tu 《地震研究进展(英文)》2022,2(2):100140
The 22 May 2021 MW 7.4 Madoi, Qinghai, China earthquake presented a rare opportunity to apply the modern unmanned aerial vehicle (UAV) photography method in extreme altitude and weather conditions to image surface ruptures and near-field effects of earthquake-related surface deformations in the remote Tibet. High-resolution aerial photographs were acquired in the days immediately following the mainshock. The complex surface rupture patterns associated with this event were covered comprehensively at 3–6 cm resolution. This effort represents the first time that an earthquake rupture in the interior of the Qinghai-Tibetan Plateau has been fully and systematically captured by such high-resolution imagery, with an unprecedented level of detail, over its entire length. The dataset has proven valuable in documenting subtle and transient rupture features, such as the significant mole-tracks and opening fissures, which were ubiquitous coseismically but degraded during the subsequent summer storm season. Such high-quality imagery also helps to document with high fidelity the fractures of the surface rupture zone (supplements of this paper), the pattern related to how the faults ruptured to the ground surface, and the distribution of off-fault damage. In combination with other ground-based mapping efforts, the data will be analyzed in the following months to better understand the mechanics of earthquake rupture related to the fault zone rheology, rupture dynamics, and frictional properties along with the fault interface. 相似文献
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野外调查表明,青海玉树MS7.1地震发生在青藏高原中部甘孜-玉树断裂的玉树段上,在玉树县结古镇至隆宝镇之间产生了一系列包括剪切破裂、张剪切破裂、压剪切破裂、张性破裂及其不连续岩桥区出现的鼓包或陷落坑(拉分盆地)、高寒地区特有的冰裂缝等地表破裂单元,它们斜列组合成整体走向约300°、长约65 km、最大同震左旋位移2.4 m的地表破裂带,具有变形局部化的基本特征.玉树地震地表破裂带整体上可划分为长约15 km的结隆次级地表破裂带和长约31 km的结古次级地表破裂带,两者呈左阶羽列,其间无地表破裂段长约17 km,对应于MW6.4和MW6.9两个次级地震事件.地表破裂类型、基本组合特征等显示出甘孜-玉树断裂两盘块体的运动方式以纯剪切的左旋走滑为主,从一个方面反映了青藏高原物质存在着向东的逃逸和挤出现象. 相似文献
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Yanbo Zhang Yueren Xu Wenqiao Li Runchao Liu Ruoyu Mu Jiayi Li Da Zhang Haofeng Li Qinjian Tian 《地震研究进展(英文)》2022,2(2):100133
At 02:04 on May 22, 2021, an MS 7.4 earthquake occurred in Madoi County in Qinghai Province, China. This earthquake is the largest seismic event in China since the 2008 MS 8.0 Wenchuan earthquake. Thus, it is critical to investigate surface deformation and damage in time to accurately understand the seismogenic structure of the Madoi earthquake and the seismogenic capacity of the blocks in this region. This study focuses on the Xuema Village, located at the eastern end of the coseismic surface ruptures produced by the event, and assesses the deformation and seismic damage in this area based on field surveys, UAV photogrammetry, and ground penetrating radar (GPR). The results indicate that the rupture scale is substantially smaller at the eastern end of the rupture zone compared to other segments. En echelon type shear tensile fractures are concentrated in a width range of 50–100 m, and the width of single fractures ranges from 20 to 30 cm. In contrast, the degree of seismic damage significantly increases at this site. All of the brick and timber houses are damaged or collapsed, while the steel frame structures and the color steel houses are slightly damaged. More than 80% of the bridge decks on the Changma River Bridge collapse, similar to the terraces along the Youerqu and Changma Rivers and the cut slopes of Provincial Highway S205. We infer that the seismogenic fault of the Madoi earthquake exerts a tail effect in this segment. The tension zone has led to a reduction at the eastern end of the rupture zone, causing shaking damage. Local topography and buildings without earthquake-resistant construction along the strike of the rupture zone have undergone different levels of seismic damage. 相似文献