The formation of the Wulipo landslide and the resulting debris flow in Dujiangyan City, China

The Wulipo landslide, triggered by heavy rainfall on July 10, 2013, transformed into debris flow,resulted in the destruction of 12 houses, 44 deaths, and 117 missing. Our systematic investigation has led to the following results and to a new understanding about the formation and evolution process of...

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Bibliographic Details
Published in:Journal of mountain science 2017-06, Vol.14 (6), p.1100-1112
Main Authors: Chen, Xing-zhang, Cui, Yi-fei
Format: Article
Language:English
Subjects:
Accumulation
Area
Chains
Collapse
Damage assessment
Debris flow
Destruction
Detritus
Disasters
Earth and Environmental Science
Earth Sciences
Ecology
Environment
Evolution
Expansion
Fatalities
Free surfaces
Geography
Hydrodynamic pressure
Hydrodynamics
Identification
Instability
Landslides
Landslides & mudslides
Mass
Mathematical models
Mudstone
Pressure
Rain
Rainfall
Risk assessment
Sandstone
Sedimentary rocks
Sliding
Slope
Slopes
Slumping
Stability
Tension
Translation
中国
地质力学模型
滑动过程
滑坡体
滑坡泥石流
灾害链
诱发因素
都江堰市
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Summary:The Wulipo landslide, triggered by heavy rainfall on July 10, 2013, transformed into debris flow,resulted in the destruction of 12 houses, 44 deaths, and 117 missing. Our systematic investigation has led to the following results and to a new understanding about the formation and evolution process of this hazard. The fundamental factors of the formation of the landslide are a high-steep free surface at the front of the slide mass and the sandstone-mudstone mixed stratum structure of the slope. The inducing factor of the landslide is hydrostatic and hydrodynamic pressure change caused by heavy continuous rainfall. The geological mechanical model of the landslide can be summarized as "instability-translational slide-tension fracture-collapse" and the formation mechanism as "translational landslide induced by heavy rainfall". The total volume of the landslide is 124.6×104 m3, and 16.3% of the sliding mass was dropped down from the cliff and transformed into debris flow during the sliding process, which enlarged 46.7% of the original sliding deposit area. The final accumulation area is found to be 9.2×104 m2. The hazard is a typical example of a disaster chain involving landslide and its induced debris flow. The concealment and disaster chain effect is the main reason for the heavy damage. In future risk assessment, it is suggested to enhance the research onpotential landslide identification for weakly intercalated slopes. By considering the influence of the behaviors of landslide-induced debris flow, the disaster area could be determined more reasonably.
ISSN:1672-6316
1993-0321
1008-2786
DOI:10.1007/s11629-017-4392-1