Abstract Lantau Island, the largest outlying island of the territory of Hong Kong, experienced a severe rainstorm on 4–5 November 1993, which induced >800 slope failures on natural terrain there. Detailed field investigations were carried out to study the failure modes, in relation with various influencing factors. It was found that the occurrence of slide-debris flows has a close relationship with bedrock geology, slope gradient, vegetation cover and micro landform. The failure modes of slide-debris flows may be classified into translational slides and rotational slides, and the former are predominant. Analysis of the hydrological response of colluvial slopes during the rainstorm indicated that the majority of the failures were caused by the development of a perched water table in the thin surface layer of colluvium of volcanic origin due to infiltration during the heavy rain. Undisturbed soil samples from south Lantau have been subjected to anisotropically consolidated undrained compression tests at comparatively low stress levels. Constant deviatoric stress path tests (CQD) simulating the stress path in the field at in situ stress levels have been performed to investigate soil behavior. The CQD test results indicate that the material of slopes at undisturbed state is brought to dilation because of the increase in pore water pressure caused by infiltration of rain water. For a translational slide, the displacement, resulting from dilation, may destroy cohesion along the failure surface and locally within the interior of the slide. The surplus water during the intense rainstorm was able to equilibrate the reduction in pore pressure caused by dilation, and the dilation and displacement may be further increased. The strain-softening after significant strains triggered debris flow mobilization. However, for a rotational slide, the increase in pore water pressure caused by surplus water infiltration during the intense rainstorm could not equilibrate the reduction in pore pressure caused by dilation, much or even all of the sliding block could not mobilize into a debris flow.
[1]
J. T. Hack.
Geomorphology of the Shenandoah Valley, Virginia and West Virginia, and origin of the residual ore deposits
,
1965
.
[2]
Edwin L. Harp,et al.
Pore pressure response during failure in soils
,
1990
.
[3]
Russell H. Campbell,et al.
Soil slips, debris flows, and rainstorms in the Santa Monica Mountains and vicinity, southern California
,
1975
.
[4]
John E. Costa,et al.
Debris Flows/Avalanches: Process, Recognition, and Mitigation
,
1987
.
[5]
Donald H. Gray,et al.
Biotechnical Slope Protection and Erosion Control
,
1989
.
[6]
P. Vaughan,et al.
WEATHERING, STRUCTURE AND IN SITU STRESS IN RESIDUAL SOILS
,
1984
.
[7]
D. Greenway,et al.
Vegetation and slope stability
,
1987
.
[8]
Daniel Pradel,et al.
Effect of Permeability on Surficial Stability of Homogeneous Slopes
,
1993
.
[9]
Nicholas Sitar,et al.
Analysis of Rainfall-Induced Debris Flows
,
1995
.
[10]
R. Sidle,et al.
Hillslope stability and land use
,
1985
.
[11]
W. Dietrich,et al.
The importance of hollows in debris flow studies; Examples from Marin County, California
,
1987
.
[12]
R. W. Fleming,et al.
Transformation of dilative and contractive landslide debris into debris flows-An example from marin County, California
,
1989
.