This unique volume contains papers based on presentations and discussions at the NATO Advanced Research Workshop on Massive Rock Slope Failure; New Models for Hazard Assessment held in Celano, Italy in June 2002. 32 papers by 64 engineers, geologists, and geomorphologists from 16 countries address the issue of landslides from massive rock slope failure and associated phenomena (landslide tsunamis and landslide dams). Authors include some of the world’s leading authorities on the subject.
Amongst the thematic topics discussed are global frequency, impacts on society, analysis of initial rock slope failure, monitoring of rock slope movement, analysis and modeling of post-failure behaviour, volcanic landslides, and influences of massive rock slope failure on the geomorphological evolution of mountain regions. Regional contributions include reports on rockslides and rock avalanches in Norway, western Canada, the Andes of Argentina, the Karakoram Himalaya, the European Alps, the Appennines, and the mountains of Central Asia.
Rockslides and rock avalanches in the Central Asian republics of the former Soviet Union are discussed in detail for the first time in an English-language book. These landslides include the 1911 Usoi rockslide, that dammed 75 km-long Lake Sarez, and the 1949 Khait rock avalanche that may have killed up to 28,000 people. Both landslides were earthquake-triggered and both are located in Tajikistan. An additional highlight is a detailed description and analysis of large-scale artificial rock avalanches triggered by underground nuclear explosions during the testing programme of the former Soviet Union.
The volume is a contribution to defining the state-of-the-art in hazard assessment for massive rock slope failure and to global knowledge of the occurrence of landslides from massive rock slope failure in time and space. It is dedicated to the memory of noted Italian engineering geologist Professor Edoardo Semenza (1927-2002).
|Series:||Nato Science Series: IV: (closed) , #49|
|Product dimensions:||6.10(w) x 9.25(h) x 0.36(d)|
Table of Contents
4. From Cause to Effect - Using Numerical Modelling to Understand Rock Slope Instability Mechanisms; E. Eberhardt.- 5. Gravitational Creep of Rock Slopes as Pre-collapse Deformation and some Problems in its Modelling; A.A. Varga.- 6. Models Available to Understand Failure and Pre-failure Behaviour of Large Rock Slope Movements: The Case ofLa Clapiêre, Southern Alps, France; V. Merrien-Soukatchoff, Y. Gunzberger.- 7. Numerical Modelling ofRock Slopes Using a Total Slope Failure Approach; D. Stead, J. Coggan.- 8. The Role of Topographic Amplification on the Initiation of Rock Slope Failures During Earthquakes; W. Murphy.- PART 3: MONITORING OF ROCK SLOPE MOVEMENT. 9. Application of Ground Based Radar Interferometry to Monitor an Active Rockslide and Implications for Emergency Management; N. Casagli et al.- 10. Monitoring and Assessing State of Activity of Slope Instabilities by the Permanent Scatterers Technique; C. Colesanti et al.- PART 4: ANALYSIS OF POST-FAILURE BEHAVIOUR. 11. Forecasting Runout of Rock and Debris Avalanches; R.M. Iverson.- 12. Contjnuum Numerical Modelling of Flow-like Landslides; G.B. Crosta et al.- 13 . Landslide Mobility and the Role of Water; F. Legros.- 14. Rock Avalanche Occurrence, Process, and Modelling; O. Hunger.- 15. Mobility of Rock Avalanches Triggered by Underground Nuclear Explosions; V. V. Adushkin.- 16. Rapid Rock Mass Flow with Dynamic Fragmentation: Inferences from the Morphology and Internal Structure of Rockslides and Rock Avalanches; M.J. McSaveney, T.R.H. Davies.- 17. Morphology and Internal Structure of Rockslide and Rock Avalanches: Grounds and Constraints for their Modelling; A.L. Strom.- PART 5: CASE STUDIES OF MASSIVE ROCK SLOPE FAILURE. 18. The Flims Rockslide: History of lnterpretation and New Data; A. von Poschinger et al.- 19. Rock Avalanche and Mountain Slope Deformation in a Convex Dip-Slope: The Case of the Maiella Massif, Central Italy; G. Scarascia Mugnozza et al.- 20. Slow-Moving Disintegrating Rockslides on Mountain Slopes; R. Couture, S. G. Evans.- 21. Edoardo Semenza: The Importance of Geological and Geomorphological Factors for the Identification of the Ancient Vaiont Rockslide; M. Ghirott.-i 22. Failure Mechanisms and Runout Behaviour of Three Rock Avalanches in North Eastern Italian Alps; R. Genevois et al.- PART 6: VOLCANIC LANDSLIDES. 23. Large Modern Collapses on the Active Volcanoes of Kamchatka: Causes and Mechanisms of Formation; I. V. Melekestsev.- 24. Assessing Massive Flank Collapse at Stratovolcanoes Using 3-D Slope Stability Analysis; M.E. Reid, D.L. Brien.- 25. Catastrophic Volcanic Landslides: The La Orotava Events on Tenerife, Canary Islands; M. Hurlimann, A. Ledesma.- PART 7: REGIONAL STUDIES OF MASSIVE ROCK SLOPE FAILURE. 26. Rock Slope Failures in Norwegian Fjord Areas: Examples, Spatial Distribution and Temporal Pattern; L.H. Blikra et al.- 27. Rock Avalanching in the NW Argentine Andes as a result of Complex Interactions of Lithologic, Structural and Topographic Boundary Conditions, Climate Change and Active Tectonics.
R. L. Hermanns et al.- 28. Rock Avalanches with Complex Run Out and Emplacement, Karakoram Himalaya, Inner Asia; K. Hewitt.- 29. Dissected Rockslide and Rock-Avalanche Deposits, Tien Shan, Kyrgizstan; K. Abdrakhmatov, A.L. Strom PART 8: INFLUENCES ON GEOMORPHOLOGICAL EVOLUTION. 30. Landslide-driven Erosion and Topographic Evolution of Active Mountain Belts; N. Hovius, C.P. Stark.-31. Landslide-driven Erosion Impacts of Landslide Dams on Mountain Valley Morphology R.L. Schuster.- PART 9: STATE-OF-THE-ART. 32. Massive Rock Slope Failure: Perspectives and Retrospectives on State-of-the-Art; J.N. Hutchinson.