Stability analysis of the 2007 Chehalis lake landslide based on long-range terrestrial photogrammetry and airborne LiDAR data

Brideau, Marc-André; Sturzenegger, Matthieu; Stead, Doug; Jaboyedoff, Michel; Lawrence, Martin; Roberts, Nicholas; Ward, Brent; Millard, Thomas; Clague, John

doi:10.1007/s10346-011-0286-4

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Stability analysis of the 2007 Chehalis lake landslide based on long-range terrestrial photogrammetry and airborne LiDAR data
Citation	Brideau MA, Sturzenegger M, Stead D, Jaboyedoff M, Lawrence M, Roberts N, Ward B, Millard T, Clague J. Landslides 2012; 9(1): 75-91.
Copyright	(Copyright © 2012, Holtzbrinck Springer Nature Publishing Group)
DOI	10.1007/s10346-011-0286-4
PMID	unavailable
Abstract	On December 4th 2007, a 3-Mm 3 landslide occurred along the northwestern shore of Chehalis Lake. The initiation zone is located at the intersection of the main valley slope and the northern sidewall of a prominent gully. The slope failure caused a displacement wave that ran up to 38 m on the opposite shore of the lake. The landslide is temporally associated with a rain-on-snow meteorological event which is thought to have triggered it. This paper describes the Chehalis Lake landslide and presents a comparison of discontinuity orientation datasets obtained using three techniques: field measurements, terrestrial photogrammetric 3D models and an airborne LiDAR digital elevation model to describe the orientation and characteristics of the five discontinuity sets present. The discontinuity orientation data are used to perform kinematic, surface wedge limit equilibrium and three-dimensional distinct element analyses. The kinematic and surface wedge analyses suggest that the location of the slope failure (intersection of the valley slope and a gully wall) has facilitated the development of the unstable rock mass which initiated as a planar sliding failure. Results from the three-dimensional distinct element analyses suggest that the presence, orientation and high persistence of a discontinuity set dipping obliquely to the slope were critical to the development of the landslide and led to a failure mechanism dominated by planar sliding. The three-dimensional distinct element modelling also suggests that the presence of a steeply dipping discontinuity set striking perpendicular to the slope and associated with a fault exerted a significant control on the volume and extent of the failed rock mass but not on the overall stability of the slope.