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汶川大地震诱发地质灾害主要类型与特征研究 总被引:9,自引:1,他引:8
许强 《地质灾害与环境保护》2009,20(2):86-93
“5.12”汶川大地震诱发了数以万计的次生地质灾害,对灾区人民生命财产安全构成严重威胁,并成为影响灾区灾后恢复重建的重要因素之一。本文在对汶川I地震区地质灾害进行大量现场调查的基础上,结合室内分析模拟,对汶川地震诱发的滑坡、崩塌、不稳定斜坡(震裂山体)和泥石流等主要次生地质灾害的主要类型及特征进行了较系统地分析研究。结果表明,强震诱发滑坡灾害发生特点与岩性结构和地形条件有较明显的关系,在硬岩、软岩和松散堆积物分布区,滑坡的启动、运动和停积形式有较大的差别,但总体上都具有高速、高动能、强大动力等特征。强震诱发的崩塌主要包括高位大型崩塌;小规模块石崩落、抛射;崩塌诱发大规模滑坡3类。强震条件下大多数崩塌都表现出一定的水平抛射特征。强烈的地震动力使极震区众多山体大范围震裂松动,形成了大量震裂山体。这些震裂山体的地表裂缝具体又可细分为断裂裂缝、震裂裂缝和滑裂裂缝3类。汶川地震形成了巨量泥石流物源,再加上震后泥石流爆发的临界降雨量大大降低,其启动和运动方式发生明显改变,在今后数年内,泥石流将是影响灾区恢复重建的最大地质灾害隐患,应高度重视,采取切实有效措施加以防范。 相似文献
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汶川地震过去3a了.3a来,大量的国内外学者对地震灾区地震地质灾害的发育分布规律、形成机理及防治对策给予了高度关注,发表了大量的研究成果.人们在关注同震地质灾害的同时,更对地震灾区今后地质灾害的发生规律及演化趋势、持续时间倾注了极大的关心,因为震后连续3a,尤其是2010年,灾区地质灾害的频率和规模均出现较震前显著增大... 相似文献
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强震区同震地质灾害特点、震后地震效应研究是支撑灾后重建和防灾减灾的关键。本文基于震后重点区无人机高清遥感影像解译、震后地质灾害应急排查、极震区地质灾害详查数据,研究了同震地质灾害的数量、空间分布、控制因素,详细分析了震后地质灾害防治工作面临的3个重要风险,并针对灾后重建中关于地质灾害防治工作提出了4点建议。研究结果显示:(1)同震次生地质灾害规模以小型为主,中型次之,大型较少,主要沿大渡河两岸、交通道路沿线、大渡河右岸支流、发震断裂和其他断裂沿线等部位密集分布;(2)控制同震次生地质灾害的主要因素由强至弱分别是地震动、断裂带、地形坡度、地层岩性和强震区工程设防标准不够;(3)震后地质灾害防治主要面临降雨加剧已有灾害点变形和诱发新的灾害、震裂山体可能演变为高位远程灾害链的风险源区、巨量沟道斜坡物源构成泥石流的潜在物源并形成灾害;(4)建议加强“人技结合”的隐患识别体系机制,构建依靠科技的点面结合监测预警机制,统筹各要素科学实施避让搬迁,提高地震活跃强震区工程建设抗灾标准,构建农村切坡建房的技术支撑机制。 相似文献
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石坎河小流域位于汶川地震发震断裂-映秀—北川断裂带上,强震后流域内滑坡、泥石流等地质灾害显著增强。本文收集整理了震前、震后流域内地质灾害的数据资料,详细分析研究了流域内地质环境条件、震后9a内泥石流活动特征及其治理工程情况,在此基础上讨论其工程防治的最佳时机。通过研究得出:(1)石坎河流域支沟纵坡降大,主沟纵坡降相对较小,暴发多次泥石流灾害后支沟沟道多下切,主河道淤积严重,灾害叠加放大效应明显;(2)石坎河流域暴发多次泥石流灾害后河谷变宽,地形改变较大、物源减少明显,流域内暴发泥石流的规模逐渐减小,未来暴发的泥石流规模一般不会再超过2013年7月9日的泥石流规模;(3)石坎河流域泥石流工程防治最佳时机应为2013年7月9日泥石流灾害后。 相似文献
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汶川地震灾区高位泥石流成灾模式分析 总被引:1,自引:0,他引:1
魏昌利;何元宵;张瑛;廖维;陈亮 《中国地质灾害与防治学报》2013,(4):52-60
5·12汶川地震后,泥石流成为汶川地震灾区的主要地质灾害类型,历次暴雨均引发大量泥石流,其中高位泥石流危害大、防治难,已引起业界广泛关注,它具有物源量丰富、分布相对位置高,沟道纵比降大,泥石流暴发隐蔽性强、破坏性大等特点。本文通过对已发的高位泥石流形成条件、基本特征和成因机理研究,将其划分为"滑坡-碎屑流-泥石流型"、"支沟群发汇集型"、"堵溃型"、"阶梯沟道型"和复合型五种成灾模式,总结出了各模式的主要特点,并举典型案例进行解剖分析。对高位泥石流的深入研究和科学防治具有一定的指导和借鉴意义。 相似文献
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“4•20”芦山地震诱发地质灾害基本特征及其与“5•12”汶川地震对比分析 总被引:2,自引:0,他引:2
2013年4月20日8时2分,四川省雅安市芦山县(30.3°N,103.0°E)发生了Ms7.0级强烈地震,其是继2008年5月12日汶川Ms8.0特大地震后在龙门山断裂带上的又一次破坏性地震。文章分析了"4·20"芦山地震诱发地质灾害基本特征、形成机制和典型案例,并与"5·12"汶川地震诱发地质灾害进行了对比,在此基础上研究了两次地震地质灾害集中区断裂带活动性质、地貌特征、地形坡度、地震烈度等对崩塌滑坡的影响,主要取得了以下认识:①芦山地震诱发的地质灾害类型主要有崩塌(滚石)、滑坡、泥石流和不稳定斜坡四类,与汶川地震诱发灾害相比数量少,规模小,主要以中小型浅表层滑坡崩塌为主,且主要集中在高陡边坡和高山峡谷区;②芦山地震区宝兴县冷木沟和校场沟泥石流和2010年甘肃舟曲三眼峪、罗家峪泥石流灾害具有极为相似的地形地貌特征和孕灾条件;③芦山地震诱发地质灾害机制主要有:拉裂-崩滑-碰撞-铲刮-碎屑流、拉裂-崩落、震动-降雨-崩塌(滑动)-泥石流、震动-抛掷(滚动)四种,震后地质灾害是内外动力地质作用耦合叠加的结果;④芦山地震与汶川地震因其震级、断裂带性质及破碎程度、地形地貌等差异诱发的地质灾害存在明显的异同点,灾害类型基本相同,而方量、数量、危害等方面差异明显。 相似文献
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渔子溪下游耿达乡-映秀镇河段是汶川地震触发震害最为严重、灾害链效应最为显著的河段之一。本文通过详细的实地调查和遥感影像分析,力求揭示该河段地质灾害的特征及灾害链的成生过程、成生条件。依据震害特征,将地质灾害划分为斜坡中上部强风化岩土体失稳坠落、块状岩质边坡滑移式垮塌及局地暴雨启动型泥石流3类,并分析震害发育规律。调查表明,灾害点的空间展布受控于发震断裂,且北岸发育密度更大,茂汶断裂两侧差异显著。对51个崩塌点及17条泥石流研究发现,地震崩塌灾害主要发生在40°以上斜坡,主要分布在斜坡中上部(0.4倍坡高以上)及地貌突出部位,且大纵比降的壮年期沟谷易发泥石流。同时,诱发因素的转变致使地质灾害向降雨主导的小规模单体崩塌、泥石流方向发展。区内主要存在2种地质灾害链:(1)内动力地质灾害链"地震→崩塌→压迫河道、毁路或形成堰塞湖",其成生过程经历高速启动、滑移运动、堵河3个阶段; (2)内外动力耦合作用地质灾害链"地震→崩塌、震裂山体→暴雨→泥石流→压迫河道、毁路或形成堰塞湖",成生过程可划分为启动、堵塞(沟谷后)溃决、铺床、堵河4个阶段。灾害链的成生条件概括为:脆弱的地质环境; 强烈地震动震垮、震裂高陡斜坡(>50m,>40°); 强降雨及适宜的堵河条件。 相似文献
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2010年4月14日7时49分,青海省玉树县发生MS7.1级地震。玉树地震不仅造成大量房屋破坏与人员伤亡,同时引发了大量的崩塌、滑坡和山体裂缝,并且形成了大量的诸如泥石流、碎屑流等链生灾害隐患,造成玉树震区地质灾害分布规律与发育特征发生显著改变。通过现场调查与数据统计,对地震前后地质灾害分布规律与发育特征进行分析、研究。结果表明: 玉树震区震前地质灾害呈零星点状分布,以泥石流、不稳定斜坡为主要地质灾害类型,规模以小型为主,形成时间主要集中于每年的5~7月。震后,玉树震区地质灾害数量显著增加,在宏观震中结古镇主震断裂穿越的巴曲两岸与结古镇北部山区以及扎曲南部山区,沿主震断裂呈面状集中分布,距离主震断裂较远或远离宏观震中的区域呈零星点状分布。地质灾害受玉树主震断裂控制明显,并受坡型、坡高与坡度的控制; 地质灾害主要分布于距主震断裂2km以内的北盘区域,在坡型上主要分布于凸型与直线型坡,高程为3800~4000m内,坡度在25~40范围内,且以30~35范围内地质灾害最为发育; 地震造成山体地表裂缝所形成的地质灾害隐患比较突出,大中型规模的地质灾害数量明显增加,危害程度显著增高; 汛期地质灾害发育更加集中,并加剧冻融期地质灾害的孕育。 相似文献
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2008年5.12汶川地震是新中国成立以来破坏性最强、诱发地质灾害最严重的一次特大地震。本文简要介绍了国土资源地质大调查计划项目“汶川地震地质灾害调查评价”的主要研究进展与成果:采用空天地一体化调查、地球物理探测、GPS位移监测、斜坡地震动测试及大型物理模拟等技术,调查和研究了汶川地震地质灾害发育特征和分布规律,揭示内外动力耦合作用下的地质灾害成灾机理,并开展了震后重建区高位滑坡泥石流防治和监测预警关键技术研究,为强震山区重大地质灾害监测预警和灾后重建提供了技术支撑。 相似文献
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ZHANG Yongshuang DONG Shuwen HOU Chuntang GUO Changbao YAO Xin LI Bin DU Jianjun ZHANG Jiagui 《《地质学报》英文版》2013,87(3):646-657
Geohazards induced by the Lushan Ms 7.0 earthquake on April 20, 2013 mainly have four types: collapse, landslide, slope debris flow, and sand-soil liquefaction. These geohazards mainly occurred near the epicenter, on steep slopes or below cliffs in high mountain and deep valley areas, and at or near fault ends. They have no obvious relationships to active faults, but their relationships to the weathering degree and structures of rock and rock mass are obvious. Compared with the Wenchuan Ms 8.0 earthquake on May 12, 2008, the Lushan earthquake is relatively little in the impact force and the throwing amount. All of these should be related to the magnitude of this earthquake, not very large but not very little. This character of the Lushan earthquake would make some processes uncompleted so as to bring about some concealed geohazards. Finally, in order to deal with challenges presented by such conceal geohazards, some brief recommendations are put forward. 相似文献
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地质灾害链 总被引:6,自引:1,他引:6
用系统的普遍联系和发展的观点看待各种地质灾害之间的相互关系是地质灾害链研究的出发点。当前,地质灾害链的研究还处于起步阶段,地质灾害链的理论及其评价方法和技术还不完善。在收集相关资料的基础上,阐述了地质灾害链的定义、分类和分级,初步总结中国地质灾害链的分布规律,综合分析地质灾害链的研究现状,阐明了其发展方向,并提出地质灾害链防治的一些措施和建议。按诱发因素,地质灾害链可以分为:内动力地质灾害链、外动力地质灾害链、人类工程活动地质灾害链以及复合型地质灾害链。依据地质灾害链的规模不同,地质灾害链依次可以分为四级:一级地质灾害链,全球级别的地质灾害链;二级地质灾害链,区域地质灾害链;三级地质灾害链,流域地质灾害链;四级地质灾害链,单条冲沟地质灾害链。在中国的东部尤其是东南沿海地区台风灾害链活动频繁、影响范围广、造成的损失巨大。在青藏高原地区尤其是南北向地震带,内、外动力地质灾害链活动频繁,影响深远。地震灾害链、崩塌和滑坡转化为泥石流问题、滑坡坝溃决问题、冰湖溃决灾害链、台风灾害链等问题将是未来地质灾害链的研究重点;地质灾害链评价、预测及其风险评估将是地质灾害链研究的关键科学问题。地质灾害链的防治是地质灾害链研究的最终目标。 相似文献
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滇藏铁路滇西北段主要地质灾害类型及发育规律的探讨 总被引:5,自引:0,他引:5
滇藏铁路滇西北段位于青藏高原东南缘向云贵高原的过渡部位,地貌复杂、峡谷深切,新构造运动十分强烈,地震活动频繁。该区的降雨主要集中在5~10月份,降雨强度大且集中。复杂的地质环境加之降雨、人类活动等外部因素造成该地区成为崩塌、滑坡和泥石流等地质灾害多发区,常引起交通中断、毁坏房屋及人员伤亡事故。本文在野外地质调查的基础上,着重阐述了滇藏铁路滇西北段主要地质灾害类型及发育规律,对于减少和预防铁路遭受崩塌、滑坡和泥石流等的危害具有重要的理论和实际意义。 相似文献
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The Wenchuan Earthquake (May 12, 2008), Sichuan Province,China, and resulting geohazards 总被引:19,自引:5,他引:14
Peng Cui Xiao-Qing Chen Ying-Yan Zhu Feng-Huan Su Fang-Qiang Wei Yong-Shun Han Hong-Jiang Liu Jian-Qi Zhuang 《Natural Hazards》2011,56(1):19-36
On Monday, May 12, 2008, a devastating mega-earthquake of magnitude 8.0 struck the Wenchuan area, northwestern Sichuan Province,
China. The focal mechanism of the earthquake was successive massive rock fracturing 15 km in depth at Yingxiu. Seismic analysis
confirms that the major shock occurred on the Beichuan–Yingxiu Fault and that aftershocks rapidly extended in a straight northeast–southeast
direction along the Longmenshan Fault zone. Fatalities approaching a total of 15,000 occurred, with a significant number resulting
from four types of seismically triggered geohazards—rock avalanches and landslides, landslide-dammed lakes (“earthquake lakes”),
and debris flows. China Geological Survey has identified 4,970 potentially risky sites, 1,701 landslides, 1,844 rock avalanches,
515 debris flows, and 1,093 unstable slopes. Rock avalanches and landslides caused many fatalities directly and disrupted
the transportation system, extensively disrupting rescue efforts and thereby causing additional fatalities. Landslide-dammed
lakes not only flooded human habitats in upstream areas but also posed threats to potentially inundated downstream areas with
large populations. Debris flows become the most remarkable geohazards featured by increasing number, high frequency, and low
triggering rainfall. Earthquake-triggered geohazards sequentially induced and transformed to additional hazards. For example,
debris flows occurred on rock avalanches and landslides, followed by landslide-dammed lakes, and then by additional debris
flows and breakouts of the landslide-dammed lakes and downstream flooding. Earthquake-induced geohazards occurred mainly along
the fault zone and decreased sharply with distance from the fault. It can be anticipated that post-earthquake geohazards,
particularly for debris flows, will continue for 5–10 years and even for as long as 20 years. An integrated strategy of continuing
emergency response and economic reconstruction is required. The lesson from Wenchuan Earthquake is that the resulted geohazards
may appear in large number in active fault regions. A plan for geohazard prevention in the earthquake-active mountainous areas
is needed in advance. 相似文献
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四川5.12地震次生地质灾害的基本特征初析 总被引:32,自引:11,他引:21
2008年5月12日14时28分, 四川汶川发生里氏8.0级地震给灾区人民带来了巨大的灾难和损失, 特别是山区地震次生地质灾害所带来的严重后果是人们始料未及的.本文主要报道了四川境内震中附近几个重灾山区的地震次生地质灾害的初步调查成果, 简要论述了地震诱发的滑坡、崩塌、泥石流、地裂缝和沙土液化等次生地质灾害发育特征及其危害, 提出了地震次生地质灾害某些发育规律方面一些认识和今后需要进一步研究的问题, 对于灾后重建和高烈度区城镇规划具有一定的指导意义. 相似文献
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Rapid Identification and Emergency Investigation of Surface Ruptures and Geohazards Induced by the M_s 7.1 Yushu Earthquake 总被引:1,自引:0,他引:1
ZHANG Yongshuang YAO Xin XIONG Tanyu MA Yinsheng HU Daogong YANG Nong GUO Changbao 《《地质学报》英文版》2010,84(6):1315-1327
<正>The rapid identification based on InSAR technology was proved to be effective in our emergency investigation of surface ruptures and geohazards induced by the Yushu earthquake.The earthquake-generating fault of the Yushu earthquake is the Yushu section of the Garze-Yushu faults zone.It strikes NWW-NW,23 km long near the Yushu County seat,dominated by left-lateral strike slip,and appearing as a surface rupture zone.The macroscopic epicenter is positioned at Guo-yang-yan -song-duo of Gyegu Town(33°03'11"N,96°51'26"E),where the co-seismic horizontal offset measured is 1.75 m.Geohazards induced by the Yushu earthquake are mainly rockfalls,landslides,debris flows, and unstable slopes.They are controlled by the earthquake-generating fault and are mostly distributed along it.There are several geohazard chains having been established,such as earthquake,canal damage,soil liquefying,landslide-debris flow,earthquake,soil liquefying,roadbed deformation,etc.In order to prevent seismic hazards,generally,where there is a visible surface rupture induced by the Yushu earthquake,reconstruction should be at least beyond 20 m,on each side,from it.Sufficient attention should also be given to potential geohazards or geohazard chains induced by the earthquake. 相似文献
18.
四川汶川地震地质灾害活动强度分析评价 总被引:21,自引:5,他引:16
为了探索区域群发地质灾害活动强度评价方法和指标体系,以汶川地震诱发地质灾害活动强度评价为例,在简单分析汶川地震地质灾害宏观特征的基础上,利用高精度遥感解译资料和GIS技术,计算汶川地震诱发地质灾害分布最大面密度,结合对近年来陕西宝鸡市地质灾害调查统计的历史资料分析,提出以地质灾害分布最大面密度为衡量区域地质灾害活动强度指标的基本思路和分级标准,初步建立了地质灾害活动强度指数8级划分标准,并计算出汶川地震诱发地质灾害活动强度指数最高为7级,属于极端强烈活动。其中,地质灾害活动最强地段(7级活动区)位于强震震中区映秀镇附近的岷江两岸和绵竹汉旺镇银厂沟上游发震断裂两侧;次强地段(6级活动区)位于北川县城湔河两岸和平武县南坝镇北东小流域两岸。初步揭示:地质灾害活动强度从发震断裂带向两侧具有明显衰减的趋势。最后,简要讨论了汶川地震引发地质灾害活动如此强烈的主要原因及其发展趋势。 相似文献
19.
Landslide hazards triggered by the 2008 Wenchuan earthquake, Sichuan, China 总被引:35,自引:16,他引:19
The 2008 Wenchuan earthquake (M
s = 8.0; epicenter located at 31.0° N, 103.4° E), with a focal depth of 19.0 km was triggered by the reactivation of the Longmenshan
fault in Wenchuan County, Sichuan Province, China on 12 May 2008. This earthquake directly caused more than 15,000 geohazards
in the form of landslides, rockfalls, and debris flows which resulted in about 20,000 deaths. It also caused more than 10,000
potential geohazard sites, especially for rockfalls, reflecting the susceptibility of high and steep slopes in mountainous
areas affected by the earthquake. Landslide occurrence on mountain ridges and peaks indicated that seismic shaking was amplified
by mountainous topography. Thirty-three of the high-risk landslide lakes with landslide dam heights greater than 10 m were
classified into four levels: extremely high risk, high risk, medium risk, and low risk. The levels were created by comprehensively
analyzing the capacity of landslide lakes, the height of landslide dams, and the composition and structure of materials that
blocked rivers. In the epicenter area which was 300 km long and 10 km wide along the main seismic fault, there were lots of
landslides triggered by the earthquake, and these landslides have a common characteristic of a discontinuous but flat sliding
surface. The failure surfaces can be classified into the following three types based on their overall shape: concave, convex,
and terraced. Field evidences illustrated that the vertical component of ground shaking had a significant effect on both building
collapse and landslide generation. The ground motion records show that the vertical acceleration is greater than the horizontal,
and the acceleration must be larger than 1.0 g in some parts along the main seismic fault. Two landslides are discussed as
high speed and long runout cases. One is the Chengxi landslide in Beichuan County, and the other is the Donghekou landslide
in Qingchuan County. In each case, the runout process and its impact on people and property were analyzed. The Chengxi landslide
killed 1,600 people and destroyed numerous houses. The Donghekou landslide is a complex landslide–debris flow with a long
runout. The debris flow scoured the bank of the Qingjiang River for a length of 2,400 m and subsequently formed a landslide
dam. This landslide buried seven villages and killed more than 400 people. 相似文献
20.
汶川八级地震地质灾害研究 总被引:118,自引:15,他引:103
汶川地震触发了15000多处滑坡、崩塌、泥石流,估计直接造成2万人死亡。地质灾害隐患点达10000余多处,以崩塌体增加最为显著,反映出地震对山区高陡斜坡的影响差异性非常大,在山顶上的放大作用非常显著。通过综合分析堰塞湖库容、滑坡坝高以及坝体物质组成和结构,对地震形成的33处坝高大于10m的滑坡堰塞湖进行了评估,划分出极高、高、中和低4种溃决危险。汶川地震滑坡滑床往往不具连续平整的滑面,尖点撞击是极震区滑坡的一大共性,可以分为勺型滑床、凸型滑床和阶型滑床等类型。据实地调查,滑坡附近震毁建筑物垂向震动非常明显,具有地震抛掷撞击崩裂高速滑流三阶段特征。在高速滑流中,发生3种效应:(1)高速气垫效应,滑坡体由较大块石和土构成,具有一定厚度,飞行行程可达1~3km;(2)碎屑流效应,撞击粉碎的土石呈流动状态,特别是含水丰富时,形成长程流滑;(3)铲刮效应,巨大撞击力导致下部岩体崩裂,形成新滑坡、崩塌,但是,其厚度不大,滑床起伏不平。本文以北川城西滑坡和青川东河口滑坡为例,分析了地震滑坡高速远程滑动及成灾机理。北川县城城西滑坡导致1600人被埋死亡,数百间房屋被毁,是汶川地震触发的最严重的滑坡灾难,举世罕见。青川东河口滑坡碎屑流是汶川地震触发的较为典型的高速远程复合型滑坡,滑程约2400m,高速碎屑流冲抵清江河左岸,形成滑坡坝,致使7个村庄被埋,约400人死亡。 相似文献