Book contents
- Landslides
- Landslides
- Copyright page
- Contents
- Contributors
- Preface
- 1 Landslide hazard and risk
- 2 Landslides in the Earth system
- 3 Earthquake ground motion and patterns of seismically induced landsliding
- 4 Landslides at stratovolcanoes initiated by volcanic unrest
- 5 Mobility of long-runout rock avalanches
- 6 Rapid rock-slope failures
- 7 Risk assessments for debris flows
- 8 Landslides in quick clay
- 9 Controls on the distribution of major types of submarine landslides
- 10 Tsunami hazard assessment related to slope failures in coastal waters
- 11 Physical impacts of climate change on landslide occurrence and related adaptation
- 12 Landslides and geologic environments
- 13 Numerical modeling of rock-slope instability
- 14 Remote sensing techniques and landslides
- 15 Engineering geomorphology of landslides
- 16 Developments in landslide runout prediction
- 17 Models of the triggering of landslides during earthquakes
- 18 Slow rock-slope deformation
- 19 Landslide monitoring:
- 20 Groundwater in slopes
- 21 Soil slope stabilization
- 22 Rockfall characterization and modeling
- 23 The 2006 Eiger rockslide, European Alps
- 24 Randa:
- 25 Characterization and management of rockslide hazard at Turtle Mountain, Alberta, Canada
- 26 The Åknes rockslide, Norway
- 27 A seismometric approach for back-analyzing an unusual rockfall in the Apennines of Italy
- 28 Downie Slide, British Columbia, Canada
- 29 The 1963 Vaiont landslide, Italy
- 30 Hong Kong landslides
- 31 Landslides induced by the Wenchuan earthquake
- 32 Landslides on other planets
- Index
6 - Rapid rock-slope failures
Published online by Cambridge University Press: 05 May 2013
Book contents
- Landslides
- Landslides
- Copyright page
- Contents
- Contributors
- Preface
- 1 Landslide hazard and risk
- 2 Landslides in the Earth system
- 3 Earthquake ground motion and patterns of seismically induced landsliding
- 4 Landslides at stratovolcanoes initiated by volcanic unrest
- 5 Mobility of long-runout rock avalanches
- 6 Rapid rock-slope failures
- 7 Risk assessments for debris flows
- 8 Landslides in quick clay
- 9 Controls on the distribution of major types of submarine landslides
- 10 Tsunami hazard assessment related to slope failures in coastal waters
- 11 Physical impacts of climate change on landslide occurrence and related adaptation
- 12 Landslides and geologic environments
- 13 Numerical modeling of rock-slope instability
- 14 Remote sensing techniques and landslides
- 15 Engineering geomorphology of landslides
- 16 Developments in landslide runout prediction
- 17 Models of the triggering of landslides during earthquakes
- 18 Slow rock-slope deformation
- 19 Landslide monitoring:
- 20 Groundwater in slopes
- 21 Soil slope stabilization
- 22 Rockfall characterization and modeling
- 23 The 2006 Eiger rockslide, European Alps
- 24 Randa:
- 25 Characterization and management of rockslide hazard at Turtle Mountain, Alberta, Canada
- 26 The Åknes rockslide, Norway
- 27 A seismometric approach for back-analyzing an unusual rockfall in the Apennines of Italy
- 28 Downie Slide, British Columbia, Canada
- 29 The 1963 Vaiont landslide, Italy
- 30 Hong Kong landslides
- 31 Landslides induced by the Wenchuan earthquake
- 32 Landslides on other planets
- Index
Summary
Our life is short. The memory of mankind as a whole is poor. The few mountain collapses that we experience in our lifetime leave us with the impression that these collapses are very exceptional, extraordinary events. However, that is not the case. Mountain collapses are normal events in the mountains, especially in the high mountains, where they have an important natural role to play in helping to form and shape the mountains; a process that continues relentlessly and steadily. In the mountains we have to expect mountain collapses from time to time, from place to place.
(A. Heim, 1932)
- Type
- Chapter
- Information
- LandslidesTypes, Mechanisms and Modeling, pp. 59 - 70Publisher: Cambridge University PressPrint publication year: 2012
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