Runout Prediction of Debris Flows and Similar Mass Movements

2013 ◽  
pp. 221-229 ◽  
Author(s):  
Christian Scheidl ◽  
Dieter Rickenmann ◽  
Brian W. McArdell
Keyword(s):  
Debris Flows ◽  
Mass Movements

Terrestrial record of rapid mass movements in the Sawtooth Range, Ellesmere Island, Northwest Territories, Canada

1998 ◽  
Vol 35 (1) ◽  
pp. 55-64 ◽  
Author(s):  
Antoni G Lewkowicz ◽  
James Hartshorn
Keyword(s):  
Debris Flow ◽  
Debris Flows ◽  
Growth Curves ◽  
Mass Movements ◽  
Mountain Front ◽  
Order Of Magnitude ◽  
Ice Wedge ◽  
Recurrence Intervals ◽  
Rapid Mass ◽  
Lichen Growth

Widespread clastic deposits, 80-1800 m long, on the eastern side of the Sawtooth Range are the result of debris flow and slushflow. Small hillslope debris flows (10-103 m3), originating on talus slopes at the mountain front and not associated with preexisting gullies, and large channelized debris flows (103-104 m3), debouching from basins within the mountains, are comparable morphologically to those in other high-latitude and high-altitude environments. Channelized deposits are often modified by the effects of slushflow and fluvial activity. Provisional lichen growth curves for the area were produced by correlation of thallus size with the enlargement of ice-wedge polygon troughs. Lichenometry and aerial photograph interpretation were used to estimate the age of deposits so that event frequencies and rates of geomorphic work could be calculated. Vertical transport by rapid mass movements during the 20th Century averaged 17 x 103 Mg ·m ·a-1 ·km-2 ( ± half an order of magnitude), corresponding to a rock denudation rate of 0.05 mm ·a-1 for the basins and peaks feeding the east-facing slopes. Channelized debris flow produced more than 70% of this transport. Several of these large flows occurred in each of the three periods of 30-35 years examined, so their recurrence intervals are substantially shorter than values reported from locations in northern Scandinavia and Spitzbergen.

River morphology evolution driven by mass movements in tectonic active regions – A negative feedback response of transient landscape

2021 ◽  
Author(s):  
Guo-An Yu ◽  
He Qing Huang ◽  
Weipeng Hou
Keyword(s):  
Equilibrium State ◽  
Negative Feedback ◽  
Debris Flows ◽  
Grand Canyon ◽  
Active Regions ◽  
Tibet Plateau ◽  
River Morphology ◽  
Mass Movements ◽  
Lower Reach ◽  
Fluvial Processes

<p>Incised valleys or steep slopes in tectonic active mountain areas are normally in a critical equilibrium state which is highly fragile and prone to deviate under exotic disturbances (e.g., earthquake, heavy precipitation, or even human activities), inducing mass movements (e.g., landslides, avalanche, and/or debris flows). Mass movements have great impacts on fluvial processes and may even reshape valley morphology, hence are powerful drivers to river evolution in those environments. Unfortunately, compared to the mass movements themselves (e.g., occurrence time, volume, dynamics and underlying mechanisms), less attention has been paid to the fluvial processes (in a short/intermediate-term) and the long-term evolution of river morphology corresponding to (and after) those mass movements (especially catastrophic ones). This motivates the current work.</p><p>The southeast Tibet, located on the east Qinghai-Tibet Plateau, is one of the most active regions globally in terms of tectonic motion and rates of uplift. Rivers in the lower Yalung Tsangpo basin in this area are investigated to understand the morphodynamics influenced by modern and historical mass movements and examine the feedbacks of fluvial processes to mass movements. River reaches influenced by typical mass movements were chosen for detailed field surveys, including: (1) the upper part of the Yalung Tsangpo Grand Canyon which has been seriously impacted by avalanches and debris flows from tributary gullies originating at glacial mountains of Namcha Barwa and Gyala Peri; (2) the lower reach of the Yigong River covering the Yigong Landslide from the Zhamunong Gully; (3) the lower reach of the Palong River influenced by debris flows from Guxiang and Tianmo gullies; and (4)  the upper and middle reaches of the Palong River (extending roughly from Ranwu Lake to the upstream of Guxiang Lake) influenced by glacial processes and other induced mass movements since the last glacial maximum. Remote sensing images before and after the large-scale mass movements in recent decades were also used to track the corresponding river morphology variation.</p><p>Due to very high transport rate and volume of sediment incoming, mass movements have caused dramatic channel processes in east Tibet. Some even dammed the river, forming knickpoints and reshaping valley morphology. The morphology of the valleys in this area normally show alternating sections of gorges and wide valleys, with a staircase-like longitudinal profile. The gorge sections exhibit single and deeply incised channels with a high-gradient channel bed and terraces. In contrast, the wide valley sections consist of lakes, braided or anabranching channels, gentle bed gradients, and thick alluvial deposits. In recent decades, mass movements (mostly debris flows), occurred more frequently through gullies in the reaches of gorge sections than through gullies along the wide valley sections. Mass movements deviate river morphology and slope from (quasi-)equilibrium to non-equilibrium state, however, with attendant rapid sediment incoming, valley bottom siltation and erosion benchmark rising, it triggers a negative feedback which drives the river morphology to a new round of development towards equilibrium.</p>

Assessing the impact of mass movements on alpine trails and huts using EO data

2020 ◽  
Author(s):  
Florian Albrecht ◽  
Daniel Hölbling ◽  
Lorena Abad ◽  
Zahra Dabiri ◽  
Gerald Reischenböck ◽  
...  
Keyword(s):  
Natural Hazards ◽  
Debris Flows ◽  
Mass Movement ◽  
Tourism Industry ◽  
Landslide Susceptibility Mapping ◽  
User Requirements ◽  
Mass Movements ◽  
Infrastructure Management ◽  
Austrian Alps ◽  
The Impact

<p>The alpine infrastructure of trails and huts is an essential asset for summer tourism in the Austrian Alps. Every year, around five million people use the trail network for hiking and other mountaineering activities. Mass movements such as shallow landslides, debris flows and rockfalls cause significant damages to the alpine infrastructure and may block access to certain mountain areas for weeks or even months. Such damages require repair and increased maintenance activity or even rerouting of trails. Climate change will exacerbate the problem as more frequent and severe mass movements can be expected. Therefore, the Alpine associations have to take natural hazards into account for their trail and hut management.</p><p>A promising opportunity for assessing the impact of natural hazards on alpine infrastructure arises through the new generation of Earth observation (EO) satellites of the European Copernicus programme. The high spatial and temporal resolution allows the detection of mass movements with an impact on trails and huts.</p><p>Therefore, we initiated the project <em>MontEO</em> (<em>The impact of mass movements on alpine trails and huts assessed by EO data</em>) to investigate the opportunities for EO-based mass movement mapping and hazard impact assessment for alpine infrastructure. We start with a user requirements analysis that describes the demand for consistent and appropriate information on mass movements for alpine infrastructure management. We perform interviews with the Alpine associations and other relevant stakeholders. They help us to identify significant mass movements, their impact on the alpine infrastructure, and the actions that trail keepers and hut facility managers take to deal with the impacts. Based on this, we assess the suitability of EO-derived mass movement information for alpine infrastructure management, and define requirements for its production and delivery.</p><p>Based on the user requirements, we develop a multi-scale approach and combine optical and synthetic aperture radar (SAR) satellite data (e.g. Sentinel-1/2, Pléiades) to comprehensively map mass movements and to detect mass movement hotspots. Further, we integrate the EO-based mapping results with ancillary data for landslide susceptibility mapping, and for modelling and simulating rockfalls and debris flows. Finally, we analyse the network of trails and huts in relation to the obtained mass movement information and thereby assess their impact on alpine infrastructure, i.e. identify the trails and huts that are (potentially) affected by mass movements.</p><p>We demonstrate the concept and methods for three study areas in the Austrian Alps: Großarl and Kleinarl Valley in Salzburg, Karwendel in Tyrol, and the Salzkammergut in central  Austria. For these areas, we will create EO-based mass movement inventory maps, hotspot maps, and hazard impact maps. We validate our results in close collaboration with the users and analyse their usefulness for alpine infrastructure maintenance and management. The outcomes of <em>MontEO</em> will contribute to improved maintenance efficiency and will lead to a safer alpine infrastructure with an increased value for hikers, the tourism industry and the society.</p>

scholarly journals Perencanaan Pembangunan

2021 ◽  
Author(s):  
Susiati Susiati
Keyword(s):  
Debris Flows ◽  
Mass Movements ◽  
Check Dam ◽  
Sediment Discharge ◽  
Rainfall Analysis ◽  
Sediment Volume ◽  
Flood Discharge ◽  
Calculation Results ◽  
Dam Building ◽  
The City

Abstarct.Ambon city, which mostly consists of hilly areas, is an area that is very highly susceptible to the occurrence of debris mass movements, both in the form of debris flows and landslides (debris flows, erosions, and slope failures). In the city of Ambon, rivers are passed such as Way Ruhu, Way Batu Merah, Way Tantui, Way Tomu, Way Batu Gajah and Way Batu Hang. The purpose of this paper is to plan the check dam building for Way Batu Merah – Ambon City. The method used is Hydrological Analysis: hydrology as the basis for planning the Q25 Check Dam Building, which consists of rainfall analysis and the basis for calculating the planned discharge used in planning, using the Sabo Technical Center method. From the calculation results, it is obtained that the planned Q25 flood discharge of the Way Batu Merah River is 516.43 m / year with a return period of 25 years, the sediment volume can be accommodated 22,102 m / year and controlled by the Check Dam 56,050 m / year, then with a sediment discharge of 60,685 m³ / year . By comparing the amount of sediment that enters the Check Dam with the capacity of the Check Dam, it is dredged again for 3.5 years.Keywords: Sediment; Hydrological Analysis; Checkdam; Sediment Discharge

scholarly journals Depositional and erosional landforms in the Lothar Khola watershed, Central Nepal

1999 ◽  
Vol 19 ◽  
Author(s):  
V. Dangol ◽  
P. D. Ulak
Keyword(s):  
Debris Flows ◽  
Sediment Accumulation ◽  
Friction Angle ◽  
Mass Movements ◽  
Residual Soils ◽  
Landslide Area ◽  
Land Use Pattern ◽  
Central Nepal ◽  
Slide Area ◽  
Landslide Distribution

The high intensity rainfall of 19 and 20 July 1993 triggered off a large number of mass movements in the Lothar Khola watershed of Central Nepal. Most of the slides were reactivated on highly fractured and weathered rocks during the downpour. Among more than 40 landslides encountered in the watershed, the large rockslides were found at Purbangkhani, Karse, and Loling. A detailed study of landslide distribution in the watershed revealed that mos t of the landslides (about 65 % of the total landslide area) occurred on slopes ranging from 26 to 40°. These slopes were nearly equal to or a little steeper than the internal friction angle of constituting soil or rock mass. According to land use pattern, more than two thirds of the landslide area fell in the forestland and there were no landslides on the grassland. Similarly, rockslides were concentrated (about 53% of the total rockslide area) on slopes covered by slates and phyllites. On the other hand, an overwhelming majority of soil slides (more than 85% of the total soil slide area) occurred on residual soils. Debris flows were also very common in the Lothar Khola watershed. During the debris flow, from 1 to 3 m deepening of the riverbed was observed in many erosional zones whereas the sediment accumulation reached up to 4 m in the depositional zones.

Qualitative analysis of the impact of mass movements on the alpine hiking infrastructure

2021 ◽  
Author(s):  
Florian Albrecht ◽  
Daniel Hölbling ◽  
Lorena Abad ◽  
Zahra Dabiri ◽  
Gabriela Scheierl ◽  
...  
Keyword(s):  
Debris Flows ◽  
Mass Movement ◽  
Tourism Industry ◽  
Mass Movements ◽  
Infrastructure Management ◽  
Structured Interviews ◽  
Entire Area ◽  
Alpine Regions ◽  
Radar Satellite ◽  
The Impact

<p>The hiking infrastructure of trails and huts is a strong asset for summer tourism in the Austrian Alps. However, this infrastructure is prone to different types of mass movements, such as rainfall-induced shallow landslides, debris flows and rockfalls, that potentially block the access to mountain huts and hiking routes for weeks or even months. Thus, alpine infrastructure management has an increased need for information about mass movements that affect trails.</p><p>The project <em>MontEO</em> ("The impact of mass movements on alpine trails and huts assessed by Earth observation (EO) data") aims for a better understanding of the diverse impacts of mass movements on the alpine infrastructure and the related efforts for infrastructure management and maintenance, by mass movement mapping and susceptibility modelling. We performed a user requirements analysis that identified relevant stakeholders and pinpointed both user needs and requirements for information about mass movement impact on alpine infrastructure. Semi-structured interviews with trail keepers and other stakeholders revealed information about the relevance of the topic for the respective organisation, the role of the interviewed person within the organisation and the experiences and tasks that relate to mass movements.</p><p>Our preliminary results identified sections of alpine associations, tourism associations, and alpine farmers as the main stakeholders that assume responsibility for operating the trails. The interviews with trail keepers, alpine association officials and professional trail builders indicated that they consider information on mass movement particularly valuable for mid- to long-term planning of maintenance efforts and revisions, as well as for the construction of new and the re-location of existing trails. Damage due to mass movements is mainly relevant in high alpine regions and in locations where terrain and environmental conditions favour them. An example of how mass movements can affect infrastructure is a rockfall damaging safety ropes and feeding a scree that becomes a source for debris flows covering the existing path. Resulting maintenance efforts include the restoration of a debris-covered trail and the re-installation of safety ropes along the trail by a skilled builder with heavy equipment. If situated in a heavily affected region, the frequency of damage from mass movements may render the trail too costly to maintain. Either it needs to be relocated to a new route in less landslide-prone terrain or it has to be given up entirely.</p><p>Currently, we are in the process of mapping mass movements with optical and radar satellite data in four Austrian study areas. Combining the mass movement mapping and susceptibility modelling results with estimated efforts for trail maintenance will enable the detailed assessment of the mass movement impact for an entire area of responsibility of the section of an alpine association. If the validation with stakeholders proves that the impact assessment can be used in strategic trail management or the planning of maintenance activities, the <em>MontEO</em> project will result in a safer alpine infrastructure and an increased value for the tourism industry.</p>

Information on gravitational mass movements obtained from the spectrograms of their seismic signals generated

2021 ◽  
Author(s):  
Emma Surinach ◽  
E. Leticia Flores-Márquez
Keyword(s):  
Debris Flows ◽  
Mass Movement ◽  
Seismic Signal ◽  
Quantitative Information ◽  
Gravitational Mass ◽  
Mass Movements ◽  
Seismic Signals ◽  
Signal Onset ◽  
Different Types ◽  
Processing Techniques

<p>An understanding of the characteristics of a mass movement descending a slope enables us to obtain a better control through models and also to reduce its associated risks. The seismic signals generated by the mass movement are mainly caused by friction of the moving mass on the ground. Most of the studies of the seismic signals use the spectrograms as a complementary information of the signals. Our study seeks to expand the current applications of the spectrograms using the information contained in them. A spectrogram represents the evolution in time of the frequency content of a time series. It can also be read as a 3D representation of amplitude, frequency and time of the seismic signal. The spectrograms of the seismic signals generated by a mass movement that descend a slope and approach a seismic sensor can be divided into sections: SON (Signal ONset), SOV (Signal Over) and SEN (Signal End), depending on whether the gravitational mass movement is approaching the sensor, is on it or is moving away from it.</p><p>The method presented here consist of analyzing the spectrogram as an image, applying image processing techniques as “Hough Transform”. This method allows us to obtain quantitative information from the spectrograms. Our aim is to obtain the parameters of the shape of the spectrograms, focused on SON section, to create indicators linked to the evolution of the mass movement, for example the speed. The method is applied to spectrograms of three types of gravitational mass movements: snow avalanches (7), lahars (4), and debris flows (1). The results indicate similarities in the shape of the spectrograms of the different types of mass movement, prevailing, however, the specific characteristics of each type.</p>

Submarine landslides: advances and challenges

2002 ◽  
Vol 39 (1) ◽  
pp. 193-212 ◽  
Author(s):  
Jacques Locat ◽  
Homa J Lee
Keyword(s):  
Risk Assessment ◽  
Debris Flows ◽  
Mass Movement ◽  
Turbidity Currents ◽  
Mass Movements ◽  
Submarine Landslides ◽  
Sea Floor ◽  
Submarine Slides ◽  
Volcanic Islands ◽  
Movement Mechanics

Due to the recent development of well-integrated surveying techniques of the sea floor, significant improvements were achieved in mapping and describing the morphology and architecture of submarine mass movements. Except for the occurrence of turbidity currents, the aquatic environment (marine and fresh water) experiences the same type of mass failure as that found on land. Submarine mass movements, however, can have run-out distances in excess of 100 km, so their impact on any offshore activity needs to be integrated over a wide area. This great mobility of submarine mass movements is still not very well understood, particularly for cases like the far-reaching debris flows mapped on the Mississippi Fan and the large submarine rock avalanches found around many volcanic islands. A major challenge ahead is the integration of mass movement mechanics in an appropriate evaluation of the hazard so that proper risk assessment methodologies can be developed and implemented for various human activities offshore, including the development of natural resources and the establishment of reliable communication corridors.Key words: submarine slides, hazards, risk assessment, morphology, mobility, tsunami.

scholarly journals Overview: Documentation and monitoring of landslides and debris flows for mathematical modelling and design of mitigation measures – outcomes of the EGU 2011, NH session

2013 ◽  
Vol 13 (8) ◽  
pp. 2013-2016
Author(s):  
L. Franzi ◽  
M. Arattano ◽  
M. Arai ◽  
O. Katz
Keyword(s):  
Mathematical Modelling ◽  
Debris Flows ◽  
Original Work ◽  
Mitigation Measures ◽  
Future Research ◽  
General Assembly ◽  
Mass Movements ◽  
Open Session ◽  
Landslides And Debris Flows

Abstract. The papers summarised in this paper represent the scientific contributions of several scientists, coming from different countries, who work in the fields of monitoring, modelling, mapping and design of mitigation measures against mass movements. The authors participated at the 2011 EGU General Assembly presenting the contributions summarised in this paper. At the General Assembly they had the opportunity to illustrate their recent advancements, discuss each other's needs and set forth future research requirements. The scientific contributions presented here can be considered the result of the debates and the exchanges regarding their original work presented at the General Assembly that occurred either personally during the open session or during the review phase of their manuscripts.

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