The clay mineralogy, weathering and mudslide behaviour of coastal cliffs

Moore, Roger

January 1988

No description available.

631.4

Slope instability : Landslides

A block model for submarine slides involving hydroplaning

Hu, Hongrui,

January 1900

Thesis (Ph. D.)--University of Texas at Austin, 2007. / Vita. Includes bibliographical references.

Morphometric analysis of landslides and slope stability on the north shore of the John Day Reservoir, Columbia River, Oregon and Washington /

Woelke, Franziska.

January 1900

Thesis (M.S.)--Oregon State University, 1997. / Typescript (photocopy). Includes bibliographical references (leaves 125-131). Also available on the World Wide Web.

Landslides Slopes (Soil mechanics)

Experimental study of shear behavior of soils with abundant coarse particles associated with slip zones of large landslides in the Three Gorges reservoir, China

Li, Yanrong,

January 2009

Thesis (Ph. D.)--University of Hong Kong, 2009. / Includes bibliographical references (leaves 190-205). Also available in print.

Shear strength of soils Landslides

Site-specific quantitative risk assessment in the slope safety system in Hong Kong

Chan, Hoi-ting, Janet.

January 2004

Thesis (M. Sc.)--University of Hong Kong, 2004. / Also available in print.

Landslides Risk assessment

Landslide at Chainage 23+800 of Simpang Pulai-Lojing Highway, Malaysia : the observations and data interpretation /

Roslan, Norsyafina.

January 2006

Thesis (M. Sc.)--University of Hong Kong, 2006.

Landslides Slopes (Soil mechanics)

Macro-scale interaction of hillslope erosion and sediment redistribution

Sowter, Matthew James

January 2000

No description available.

551

Displacement rate effects on the residual strength of soils

Parathiras, Achilleas N.

January 1994

No description available.

624.1

Earthquakes; Landslides

New data and re-evaluation of the 1965 Hope Slide, British Columbia

Von Sacken, Rosanna S.

January 1991

The 1965 Hope Slide is one of the largest rock avalanche to have occurred in recent historic time. Although this landslide is very well known, virtually no comprehensive investigation was undertaken. This study represents a first, but essential, step to begin a detailed evaluation of the mass movement; it is also part of a research program investigating the landslide hazards along strategic transportation corridors in southwestern British Columbia (Savigny, 1990, in prep.). The geology at the slide site was confirmed to consist of greenstone and felsite, however, two varieties of each of the rock type were found: the greenstone occurs in a massive and a slightly schistose form, and the felsite occurs in a buff coloured and a greyish-white coloured variety. Discontinuities at the study site include two steeply dipping faults, three dominant sets (Jl, J2 and J3) and a shallower dipping set of joints, the orientations of the latter set closely relate to those of Jl, and a number of gouge filled shear zones along the buff felsite and greenstone contacts. The 1965 failure surface was probably controlled by two mechanisms, in which the steeper upper portion of the slope was largely controlled by pervasive step-like discontinuities (Jl and the shallower joints); the shallower lower part of the slope was controlled by gouge filled buff felsite-greenstone contacts. These two mechanisms also support the two slide events hypothesis put forward by Weichert et al. (1990), who suggested that the seismic signals recorded on the day of the landslide were the results, rather than the cause, of the mass movement(s). Based on the evidence found in this study, it is proposed that the lower slope (below the upper northeast trending fault) failed first along the gouge filled lithologic contacts, due to the debuttressing effects of the lower slope and the existing weakness along the joints, the upper slope subsequently failed. Slope stability analyses indicate that-the slope was in critical conditions prior to the 1965 slide. The results also demonstrate that the inherent weakness withinjthe rock mass was sufficient to explain the occurrence of failure without external influences. / Science, Faculty of / Earth, Ocean and Atmospheric Sciences, Department of / Graduate

Landslides -- British Columbia -- Hope

The perpetual landslide Summerland, British Columbia

Riglin, Linda Diane

January 1977

The purpose of this study is to understand the environment for failure of the Perpetual Landslide. To achieve this objective a field investigation was carried out to evaluate the movement pattern of the slide and its geologic and hydrologic environments. This information, along with ground water flow and stability models was used to define major controls on stability. The following points are made: (1) The slide moves by rotation and translation of blocks with a transition to flow movement at the toe. (2) At depth, the failure surface lies within the Tertiary sedimentary rocks. Exposed gouge consists primarily of clay (most likely remolded claystone and some clay-rich till) with dispersed pebbles and rock fragments. (3) Discontinuities including inherent heterogeneity between and within geologic units, weathering, and jointing are significant to the unstable situation. (4) Changes in stress equilibrium, particularly those caused by removal of overburden and lateral support with downcutting in Trout Creek Canyon, are likely important in the origin of the slide. (5) The proposed mechanism of failure is: (a) The progressive reduction from peak to residual strength of the claystone. (b) In addition to the high water table, high pore-water pressures along the failure surface. At the present time, the slide's continuous movement is acting to establish a new stability in equilibrium with this ground water flow system and lower strength. / Science, Faculty of / Earth, Ocean and Atmospheric Sciences, Department of / Graduate