PREDICTION OF THE BEHAVIOUR OF LANDSLIDE DAMS USING
PREDICTION OF THE BEHAVIOUR OF LANDSLIDE DAMS USING A GEOMORPHOLOGICAL DIMENSIONLESS INDEX L. ERMINI AND N. CASAGLI 陳奕愷 莊凱翔 2010. 12. 31 1
OUTLINE u INTRODUCTION u DATASET u GEOGAPHICAL DISTRIBUTION AND RELATED INFORRMATION u DAM STABILITY ASSESSMENT u POSSIBLE IMPROVEMENT TO THE MODEL AND CONCLUSION 2
INTRODUCTION Landslide dams are natural dams that form when the body of a landslide partially or completely blocks a river channel. In all cases an impoundment of water is created. This causes a serious hazard with respect to the dammed river section. The hazard is highest when it is not possible to set up promptly a control system for water drainage. As a result of a breach of a landslide dam an anomalous flood wave may propagate downstream. The higher the peak discharge originated by the dam failure, the more devastating the effects. 3
DATASET The dataset used in this paper results from the collection of data of more than 500 phenomena distributed worldwide. Data are derived from the cases inventoried by the authors themselves, most of which are located in the Northern Apennines, Italy and the western USA and from cases collected by review work. 4
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GEOGAPHICAL DISTRIBUTION AND RELATED INFORRMATION GEOGRAPHICAL DISTRIBUTION 10
GEOGAPHICAL DISTRIBUTION AND RELATED INFORRMATION LANDSLIDE DAM LONGEVITY 11
GEOGAPHICAL DISTRIBUTION AND RELATED INFORRMATION The dam longevity is fundamentally controlled by the capacity of the lake which forms upstream and the discharge of the inflowing stream. a. the hydrological balance in the watershed area upstream from the dammed section allows the lake to fill up over and above its capacity. b. the loss due to both seepage through the debris dam and evapotranspiration from the lake surface is lower than the lake inflow discharge. 滲流 + 表面蒸散 + 流出 < 流入 12
GEOGAPHICAL DISTRIBUTION AND RELATED INFORRMATION LANDSLIDE TYPE As underlined in previous investigations landslide dams may form in different geographical environments and can result from of various kinds of mass movements. 13
GEOGAPHICAL DISTRIBUTION AND RELATED INFORRMATION 14
GEOGAPHICAL DISTRIBUTION AND RELATED INFORRMATION From the diagram, landslide type is not considered to exert any control over dam evolution, and therefore this parameter cannot be used to forecast the degree of dam stability. 15
GEOGAPHICAL DISTRIBUTION AND RELATED INFORRMATION TRIGGERING CAUSES (rainfall) Most of the inventoried dams are a direct consequence of rainfall events(47 per cent): this combines both short intense and prolonged precipitation. Difficulties in setting a common boundary for these two terms in the context of a worldwide database, where various countries and climate conditions are represented. 16
GEOGAPHICAL DISTRIBUTION AND RELATED INFORRMATION Distinguishing between the two could only be performed by a detailedanalysis of hydrological data, which are not available for a statistically significant number of case histories. 17
GEOGAPHICAL DISTRIBUTION AND RELATED INFORRMATION TRIGGERING CAUSES (Earthquakesare and Volcanoes) Earthquakesare the second most frequent triggering mechanism for landslides that provoke the formation of natural dams. From the available data, it is interesting to note that only earthquakes with M > 7 trigger landslides. Often landslide dams are also consequences of the explosions of caldera volcanoes. Generally, these kinds of landslide dams are prone to collapse because of the erodibility of the materials they are formed in. 18
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GEOGAPHICAL DISTRIBUTION AND RELATED INFORRMATION DAM STABILITY ASSESSMENT BI l The dam volume considered as the main stabilizing factor since it controls the dam self-weight l The watershed area considered as the main destabilizing factor since it controls the channel discharge and stream power and indirectly the dam shape 21
GEOGAPHICAL DISTRIBUTION AND RELATED INFORRMATION Canuti et al. (1998) and Casagli and Ermini (1999), starting from the database of cases collected in the Northern Apennines, defined the blockage index (BI ), using this parameter for a preliminary forecast of blockage evolution: Vd is the landslide dam volume and Ab the catchment area. a lower boundary for cases of complete dam formation is given by BI = 3 and an upper boundary for failed dams is given by BI = 5, while a lower boundary for stable dams is given approximately by BI = 4. 22
GEOGAPHICAL DISTRIBUTION AND RELATED INFORRMATION DBI Carried out on a larger number of landslide dams by setting up a new index. All the case histories collected were ranked in the two main evolution classes (SD and UD) 23
GEOGAPHICAL DISTRIBUTION AND RELATED INFORRMATION From geomorphic analysis, best results were reached through the definition of the dimensionless blockage index (DBI ): Hd represents dam height, Vd landslide dam volume and Ab catchment area. From a physical point of view, dam height is an important variable in assessing the stability of a landslide dam against both overtopping and piping failure mechanisms. 24
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DAM STABILITY ASSESSMENT In particular a lower boundary for cases of stable dams, defined as the higher DBI value reached for the category of unstable dams, corresponds to values ranging from 3. 23 to 2. 68; while an upper boundary for failed dams, defined as the higher value reached by the DBI for the category of stable dams, corresponds to values ranging from 2. 68 to 2. 83. 26
DAM STABILITY ASSESSMENT An intuitive explanation of this result could be that cases from groups (a), (b) and (c) are located in areas quite similar both from climatic (mainly temperate regions) and geomorphic points of view, while events of group (d) are more heterogeneous. Five events are responsible for the high variability of the DBI for groups (c) and (d) and they have been analysed in detail. They can be interpreted as “exceptions” to a “common” landslide dam behaviour as generalized by the DBI. 27
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DAM STABILITY ASSESSMENT In view of these considerations, three main domains can be separated as follows: (a) DBI < 2. 75 stability domain (b) 2. 75 < DBI < 3. 08 uncertain domain (c) DBI > 3. 08 instability domain 29
POSSIBLE IMPROVEMENT TO THE MODEL AND CONCLUSION Possible improvements to this empirical model could be made by considering other variables and setting up a wider database in order to reach conclusions based on a statistical analysis. Mentioned above, a stability analysis should take into account grain size distribution of debris materials. However, in most cases understanding the role played by the grain size distribution of the debris material is difficult, because this parameter has to be compared with other variables that control the damming process. 30
CONCLUSIONS Landslide dams remain a physical process which is not well understood, because they are the result ofthe complex interaction between river and slope dynamics. The prevailing factor out of these two is often fundamental in controlling the fate of the landslide dam. By merging the already published inventories on landslide dams it is possible to increase the knowledge concerning these processes, thereby allowing more reliable forecasting analyses. 31
CONCLUSIONS A preliminary study of the newly set up database shows that landslide dams triggered by rainfall are more unstable than those mobilized by earthquakes. The reason suggested is that, usually, landslides triggered by earthquakes are capable of carrying a greater amount of material to the river channel, thus forming a more substantial landslide dam. Better results have been obtained by the definition of geomorphological indexes and particularly by the dimensionless blockage index (DBI ), based on the comparison between the basin area of the blocked river (Ab), dam volume (Vd) and dam height (Hd). 32
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