红石岩与甘家寨特大型地震崩滑体特征及其成因

doi:10.3969/j.issn.0253-4967.2017.05.012

摘要/Abstract

摘要： 2014年云南鲁甸M_S6.5地震触发了大量滑坡和崩塌，其中规模最大的是红石岩和甘家寨，二者体积均超过1 000×10⁴m³。基于震后科考，对这2个崩滑体特征和成因进行了分析。结果表明：震区位于凉山次级活动块体的前缘部位，地震活动频繁，平均6a就有1次5级以上地震发生。频繁而强烈的地震活动，对浅层岩体造成累积的破坏效应，极大地降低了斜坡的力学强度，这是红石岩、甘家寨等崩滑体发生的基础条件。红石岩特大型崩滑体，其形成与巨大的地形高差、陡峭的地形坡度、软弱地层和节理、裂隙的发育有着内在的密切联系。其形成主要经历了3个过程：第1阶段，在强震动情况下，顺河节理、卸荷裂隙以及横河向节理进一步张裂、贯通，在垂向上分割出不同的块体；第2阶段，岩体沿层间节理进一步发展，切割垂直方向的块体，形成纵横立体交叉的岩石块体；第3阶段，前2个阶段形成的岩体失去稳定，向坡下倾倒、坍塌，并沿软弱地层滑面下滑、倾倒，堵塞河道形成堰塞湖。甘家寨特大型滑坡，则为大型凹坡中下部发生的风化层滑坡，其形成过程大致为：首先，在地震力和重力的双重作用下，四周土层向凹坡中轴的下部运动、聚集，因下部松散土层含水量和容重最大，其所遭受的地震惯性力最大，最先产生塑性破坏而挤压膨胀变形；第2阶段，因坡度较陡，随着斜坡下部挤压塑性变形区进一步扩大，在斜坡中部某个部位产生拉张区，当超过风化层抗拉强度时产生破坏，滑坡体顺势快速滑出。这2个特大型滑坡代表了鲁甸地震滑坡的2种主要类型，其成因及其形成机制对该地区的地震滑坡灾害具有一定的普遍意义。

关键词: 鲁甸M_S6.5地震, 凉山次级活动块体, 累积破坏效应, 崩滑体, 凹坡地形

Abstract: The 3 August 2014 Ludian, Yunnan M_S6.5 earthquake has spawned more than 1, 000 landslides which are from several tens to several millions and over ten millions of cubic meters in volumes. Among them, the Hongshiya and Ganjiazai landslides are the biggest two with volumes over 1 000×10⁴m³. The Hongshiya and Ganjiazai landslides are two typical landslides, the former belongs to tremendous rock avalanche, and the latter belongs to unconsolidated werthering deposit landslide developed in concave mountain slope. Based on field investigations, causes and formation mechanism of the two landslides are discussed in this study. The neotectonic movement in the area maintains sustainable uplifting violently all the time since Cenozoic. The landform process accompanied with the regional tectonic uplifting is the violent downward erosion along the Jinshajiang River and its tributary, forming landforms of high mountains and canyons, deeply cut valleys, with great height difference. The regional seismo-tectonics situation suggests that:Ludian earthquake region is situated on the southern frontier boundary of Daliangshan secondary active block, and is seismically the strongest active area with one earthquake of magnitude greater than M5.0 occurring every 6 years. Frequent and strong seismicity produces accumulated effects on the ground rock to gradually lower the mechanical strength of slopes and their stability, which is the basis condition to generate large-scale collapse and landslide at Hongshiyan and Ganjiazhai. The occurring of Hongshiyan special large rock avalanche is associated with the large terrain height difference, steep slope, soft interlayer structure and unloading fissures and high-angle joints. The formation mechanism of Hongshiyan rock avalanche may have three stages as follows:Stage 1, when P wave arriving, under the situation of free surface, rocks shake violently, the pre-existent joints(in red)parallel to and normal to the river and unloading cracks are opened and connected. Stage 2, on the basis of the first stage, when S wave arriving, the ground movement aggravates. Joints(in green)along beds develop further, resulting in rock masses intersecting each other. Stage 3, rock masses lose stability, sliding downward, collapsing, and moving over a short distance along the sliding surface to the inside of the valley, blocking the river to form the dammed lake. The special large landslide at Ganjiazhai is a weathering layer landslide occurring in the middle-lower of a large concave slope. Its formation process may have two stages as follows:Firstly, under strong ground shaking and gravity, the ground rock-soil body around moves and assembles to the lower of the central axis of the large concave slope, which suffers the largest earthquake inertia force and firstly yields plastic damage to generate compression-expansion deformation, because of the largest water content and volume-weight within the loose soil of it. Secondly, in view of the steep slope, along with the compression, the plastic deformation area enlarges further in the lower of slope, giving rise to a tensional stress area along the middle of the slope. As soon as the tensional stress exceeds the tensile strength of the weathering layer, a tensional fracture will occur and the landslide rolls away immediately making use of momentum. This two large landslides are the basic typical ones triggered by the M_S6.5 Ludian earthquake, and their causes and mechanism have a certain popular implication for the landslides occurring in this earthquake region.

Key words: the M_S6.5 Ludian earthquake, the Liangshan secondary active block, accumulated destruction effects, avalanche, the concave slopes

中图分类号:

P315.2

常祖峰, 常昊, 杨盛用, 陈刚, 李鉴林. 红石岩与甘家寨特大型地震崩滑体特征及其成因[J]. 地震地质, 2017, 39(5): 1030-1047.

CHANG Zu-feng, CHANG Hao, YANG Sheng-yong, CHEN Gang, LI Jian-lin. CHARACTERISTICS AND FORMATION MECHANISM OF LARGE ROCK AVALANCHES TRIGGERED BY THE LUDIAN M_S6.5 EARTHQUAKE AT HONGSHIYAN AND GANJIAZHAI[J]. SEISMOLOGY AND GEOLOGY, 2017, 39(5): 1030-1047.

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