Your search keyword '"Mudflow"' showing total 22 results

1. Distinct periods of fan aggradation and incision for tributary valleys of different sizes along the Bailong River, eastern margin of the Tibetan Plateau

Author

Simon J. Armitage, Thomas Stevens, Guan Chen, Shiqiang Bian, Yajun Li, Xingmin Meng, and Jianhua He

Subjects

geography, Plateau, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Alluvial fan, Drainage basin, 010502 geochemistry & geophysics, 01 natural sciences, Paleosol, Aggradation, Mudflow, Tributary, Sedimentary rock, Physical geography, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

Understanding the mechanisms of fan incision/aggradation provides key insights into the dynamics of fan evolution and hazardous fan-forming processes. This paper focuses on the discrepancy in fan evolution for two nearby valleys of different catchment areas along the Bailong River. Specifically, we study fan evolution in the small-sized CJB valley (watershed area being 1.1 km2) using sedimentary analyses and 14C dating. Sedimentary logging of seven exposed profiles indicates that mudflows and debris flows are the primary fan-forming processes. Seven samples were taken from paleosols developed in mudflow sediments, and the humin fraction was extracted for 14C dating. These ages constrain the fan aggradation period to between 10 and 4.9 cal kyr BP, and then the incision period occurred after 4.9 cal kyr BP. As the mudflow sediments may contain organic matter from hillslope legacies, the fan aggradation period may be later than the 14C ages defined in this study. In any case, the time of fan incision/aggradation in CJB is younger than that of the GLP valley (watershed area being 20 km2) where fan aggradation occurred in 21.7–7 ka and incision occurred afterward. The fan aggradation period defined by the 14C ages in CJB is consistent with an alluvial fan of similar thickness in the southeastern Tibetan Plateau and two other fans along the Bailong River. This consistency may suggest a plausible climatic control on fan evolution for small-sized tributary valleys, while the inconsistency with the larger GLP valley may suggest different climate-response regimes for tributary valleys of different sizes. More research on similar types of alluvial fans and cross-validation of different dating methods is needed.

Published

2021

2. The 22 March 2014 Oso landslide, Washington, USA

Author

Robert B. Gilbert, Jean Benoît, Scott A. Anderson, Jeffrey R. Keaton, David R. Montgomery, John dela Chapelle, and Joseph Wartman

Subjects

021110 strategic, defence & security studies, 010504 meteorology & atmospheric sciences, Mass movement, Landslide classification, 0211 other engineering and technologies, Landslide, 02 engineering and technology, 01 natural sciences, Debris, Debris flow, Mudflow, Glacial period, Geomorphology, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes, Colluvium

Abstract

The Oso, Washington, USA, landslide occurred on the morning of Saturday, 22 March 2014 and claimed the lives of 43 people. The landslide began within an ~ 200-m-high hillslope comprised of unconsolidated glacial and previous landslide/colluvial deposits; it continued as a debris avalanche/debris flow that rapidly inundated a neighborhood of 35 single-family residences. An intense three-week rainfall that immediately preceded the event most likely played a role in triggering the landslide; and other factors that likely contributed to destabilization of the landslide mass include alteration of the local groundwater recharge and hydrogeological regime from previous landsliding, weakening and alteration of the landslide mass caused by previous landsliding, and changes in stress distribution resulting from removal and deposition of material from earlier landsliding. Field reconnaissance following the event revealed six distinctive zones and several subzones that are characterized on the basis of geomorphic expression, styles of deformation, geologic materials, and the types, size, and orientation of vegetation. Seismic recording of the landslide indicate that the event was marked by several vibration-generating episodes of mass movement. We hypothesize that the landslide occurred in two stages, with the first being a sequential remobilization of existing slide masses from the most recent (2006) landslide and from an ancient slide that triggered a devastating debris avalanche/debris flow. The second stage involved headward extension into previously unfailed material that occurred in response to unloading and redirection of stresses.

Published

2016

3. Initiation processes for run-off generated debris flows in the Wenchuan earthquake area of China

Author

Hu, W., Dong, X. J., Xu, Q., Wang, G. H., van Asch, T. W J, Hicher, P. Y., Landdegradatie en aardobservatie, and Landscape functioning, Geocomputation and Hydrology

Subjects

Fluidization, 010504 meteorology & atmospheric sciences, Liquefaction, Damming and breaching effect, Debris flow, 010502 geochemistry & geophysics, 01 natural sciences, Debris, Flume, Pore water pressure, Mudflow, Erosion, Run-off, Geotechnical engineering, Surface runoff, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

The frequency of huge debris flows greatly increased in the epicenter area of the Wenchuan earthquake. Field investigation revealed that runoff during rainstorm played a major role in generating debris flows on the loose deposits, left by coseismic debris avalanches. However, the mechanisms of these runoff-generated debris flows are not well understood due to the complexity of the initiation processes. To better understand the initiation mechanisms, we simulated and monitored the initiation process in laboratory flume test, with the help of a 3D laser scanner. We found that run-off incision caused an accumulation of material down slope. This failed as shallow slides when saturated, transforming the process into debris in a second stage. After this initial phase, the debris flow volume increased rapidly by a chain of subsequent cascading processes starting with collapses of the side walls, damming and breaching, leading to a rapid widening of the erosion channel. In terms of erosion amount, the subsequent mechanisms were much more important than the initial one. The damming and breaching were found to be the main reasons for the huge magnitude of the debris flows in the post-earthquake area. It was also found that the tested material was susceptible to excess pore pressure and liquefaction in undrained triaxial, which may be a reason for the fluidization in the flume tests.

Published

2016

4. Holocene evolution of halite caves in the Cordillera de la Sal (Central Atacama, Chile) in different climate conditions

Author

Linhai Yang, Jo De Waele, Mario L. V. Martina, Vincenzo Picotti, George A. Brook, Paolo Forti, De Waele, Jo, Picotti, Vincenzo, Martina, Mario L.V., Brook, George, Yang, Linhai, and Forti, Paolo

Subjects

geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Alluvial fan, 010502 geochemistry & geophysics, 01 natural sciences, Diamicton, law.invention, Cave, law, Mudflow, Paleoclimatology, Geomorphology Paleoclimate Halite caves Floods OSL dating Radiocarbon dating, Speleogenesis, Physical geography, Radiocarbon dating, Holocene, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

Geomorphological studies have been carried out in rapidly evolving salt caves related to small watersheds in the San Pedro de Atacama area, Chile. Radiocarbon ages of bones and wood from cave deposits, combined with the presence of large salt caves, geomorphological and sedimentological observations, and the results of micrometer measurements outside and in some of the caves, suggest a period of speleogenesis in the Cordillera de la Sal during the onset of the Holocene, during which the large halite cave systems developed, followed by an early Holocene hyperarid period. Most smaller caves (i.e. Lechuza del Campanario) most probably formed at the start of the wetter mid-Holocene period (5–4.4 ka), when precipitation was never intense enough to entrain large amounts of sediments, but enough to trigger cave development. A diamicton in Lechuza del Campanario Cave radiocarbon dated at ca. 4.4 ka shows that at least one high intensity rainfall event occurred in this recharge basin during the mid-Holocene wet interval. A wet period with lower intensity rainfall events followed between 4.0 and 2.5 ka, causing the 4.4 kyrs old diamicton in Lechuza del Campanario Cave to be entrenched, and the alluvial fan at the downstream end of Palacio del Sal Cave to be covered with windborne sediments dated by OSL at around 3.6 ka. At ca. 2 ka there was a high-intensity rainfall event documented by the age of a twig stuck in the ceiling of the Palacio del Sal Cave, followed by a period with lower intensity rain events until ca. 1.3 ka, when another intense flood produced a mudflow that deposited a second diamicton in Lechuza del Campanario Cave. From then on clustering of radiocarbon ages for wood and bone recovered from caves indicates increased rainfall intensity in the period ca. 0.9–0.5 ka, followed by no registered events until a minor flood at ca. 0.13 ka. The four-centuries long wetter time interval (0.9–0.5 ka), corresponding to the Medieval Climate Anomaly, has been an archeologically important period in the Atacama Desert (Tiwanaku culture). The observations and a detailed review of paleoclimate literature from this key area have allowed the development of a landscape evolution model related to changing climate conditions during the Late Holocene.

Published

2020

5. A combined geomorphological and geophysical approach to characterising relict landslide hazard on the Jurassic Escarpments of Great Britain

Author

Jonathan Chambers, M. Kirkham, Peter Hobbs, A. Merritt, David Boon, Philip R. Wilby, Catherine Pennington, and Claire Dashwood

Subjects

geography, geography.geographical_feature_category, Bedding, Lithology, Bedrock, Landslide classification, Landslide, Escarpment, Geophysics, Mudflow, Slope stability, Geomorphology, Geology, Earth-Surface Processes

Abstract

The Jurassic Escarpment in the North York Moors in Northern Britain has a high density of deep-seated relict landslides but their regional hazard is poorly understood due to a lack of detailed case studies. Investigation of a typical relict landslide at Great Fryup Dale suggests that the crop of the Whitby Mudstone Formation is highly susceptible to landslide hazards. The mudstone lithologies along the Escarpment form large multiple rotational failures which break down at an accelerated rate during wetter climates and degrade into extensive frontal mudflows. Geomorphological mapping, high resolution LiDAR imagery, boreholes, and geophysical ERT surveys are deployed in a combined approach to delimit internal architecture of the landslide. Cross-sections developed from these data indicate that the main movement displaced a bedrock volume of c. 1 × 107 m3 with a maximum depth of rupture of c. 50 m. The mode of failure is strongly controlled by lithology, bedding, joint pattern, and rate of lateral unloading. Dating of buried peats using the AMS method suggests that the 10 m thick frontal mudflow complex was last active in the Late Holocene, after c. 2270 ± 30 calendar years BP. Geomorphic mapping and dating work indicates that the landslide is dormant, but slope stability modelling suggests that the slope is less stable than previously assumed; implying that this and other similar landslides in Britain may become more susceptible to reactivation or extension during future wetter climatic phases. This study shows the value of a multi-technique approach for landslide hazard assessment and to enhance national landslide inventories.

Published

2015

6. Debris flow initiation in proglacial gullies on Mount Rainier, Washington

Author

Andrew Meigs, Gordon E. Grant, Nicholas T. Legg, and Paul Kennard

Subjects

Hydrology, geography, geography.geographical_feature_category, Sediment, Glacier, Mount Rainier, Debris, Debris flow, Mudflow, Erosion, Surface runoff, Geomorphology, Geology, Earth-Surface Processes

Abstract

article i nfo Effects of climate change, retreating glaciers, and changing storm patterns on debris flow hazards concern managers in the Cascade Range (USA) and mountainous areas worldwide. During an intense rainstorm in November 2006, seven debris flows initiated from proglacial gullies of separate basins on the flanks of Mount Rainier. Gully heads at glacier termini and widespread failure of gully walls imply that overland flow was trans- formed into debris flow along gullies. We characterized gully change and morphology, and assessed spatial distributions of debris flows to infer the processes and conditions for debris flow initiation. Slopes at gully heads were greater than ~0.35 m m �1 (19°) and exhibited a significant negative relationship with drainage area. A break in slope-drainage area trends among debris flow gullies also occurs at ~0.35 m m �1 , representing a possible transition to fluvial sediment transport and erosion. An interpreted hybrid model of debris flow initi- ation involves bed failure near gully heads followed by sediment recruitment from gully walls along gully lengths. Estimates of sediment volume loss from gully walls demonstrate the importance of sediment inputs along gullies for increasing debris flow volumes. Basin comparisons revealed significantly steeper drainage networks and higher elevations in debris flow-producing than non-debris flow-producing proglacial areas. The high slopes and elevations of debris flow-producing proglacial areas reflect positive slope-elevation trends for the Mount Rainier volcano. Glacier extent therefore controls the slope distribution in proglacial areas, and thus potential for debris flow generation. As a result, debris flow activity may increase as glacier termini retreat onto slopes inclined at angles above debris flow initiation thresholds.

Published

2014

7. Characteristics of suspended sediment and river discharge during the beginning of snowmelt in volcanically active mountainous environments

Author

Goro Mouri, Sergey Chalov, and Faizah Che Ros

Subjects

Hydrology, geography, geography.geographical_feature_category, Discharge, Sediment, Sediment transport, River discharge, Volcanic environment, Debris flow, Snowmelt, Mudflow, Suspended sediment, Tributary, Snowmelt period, Surface water, Geology, Earth-Surface Processes

Abstract

To better understand instream suspended sediment delivery and transformation processes, we conducted field measurements and laboratory experiments to study the natural function of spatial and temporal variation, sediment particles, stable isotopes, particle size, and aspect ratio from tributary to mainstream flows of the Sukhaya Elizovskaya River catchment at the beginning of and during snowmelt. The Sukhaya Elizovskaya River is located in the Kamchatka Peninsula of Russia and is surrounded by active volcanic territory. The study area has a range of hydrological features that determine the extreme amounts of washed sediments. Sediment transported to the river channels in volcanic mountainous terrain is believed to be strongly influenced by climate conditions, particularly when heavy precipitation and warmer climate trigger mudflows in association with the melting snow. The high porosity of the channel bottom material also leads to interactions with the surface water, causing temporal variability in the daily fluctuations in water and sediment flow. Field measurements revealed that suspended sediment behaviour and fluxes decreased along the mainstream Sukhaya Elizovskaya River from inflows from a tributary catchment located in the volcanic mountain range. In laboratory experiments, water samples collected from tributaries were mixed with those from the mainstream flow of the Sukhaya Elizovskaya River to examine the cause of debris flow and characteristics of suspended sediment in the mainstream. These findings and the geological conditions of the tributary catchments studied led us to conclude that halloysite minerals likely comprise the majority of suspended sediments and play a significant role in phosphate adsorption. The experimental results were upscaled and verified using field measurements. Our results indicate that the characteristics of suspended sediment and river discharge in the Sukhaya Elizovskaya River can be attributed primarily to the beginning of snowmelt in volcanic tributaries of the lahar valley, suggesting a significant hydrological contribution of volcanic catchments to instream suspended sediment transport. Daily fluctuations in discharge caused by snowmelt with debris flow were observed in this measurement period, in which suspended sediment concentration is ~ 10 mg/l during nonflooding periods and ~ 1400 mg/l when flooding occurs. The oxygen and hydrogen isotope measurements, when compared with Japan, indicated that the Kamchatka region water is relatively lightweight, incorporating the effects of topography; and the water from the beginning of the snowmelt is relatively lightweight when compared with water from the end of the snowmelt. The trend line of isotopes from the beginning of the snowmelt was defined by a slope of 6.88 (n = 12; r2 = 0.97), significantly less than that of isotopes from the snowmelt (8.72). The sediment particles collected during the snowmelt were round in shape caused by the extreme flows and high discharge. The shape of the sediment particles collected at the beginning of the snowmelt, assumed to be fresh samples from the hillslope, was sharper caused by the relatively small discharge by moderate snowmelt. Finally, the relationship between river discharge and suspended sediment concentration was indicated. The results are compared with mountainous rivers of Japan and Malaysia. A new diagram is proposed to describe the relationship between suspended sediment concentration and river discharge.

Published

2014

8. Scale amplification of natural debris flows caused by cascading landslide dam failures

Author

Jiang Zhang, Xing-Hua Zhu, Gordon G. D. Zhou, and Peng Cui

Subjects

Hydrology, geography, Landslide dam, geography.geographical_feature_category, Mudflow, Landslide classification, Erosion, Landslide, Ravine, Debris, Geology, Earth-Surface Processes, Debris flow

Abstract

Debris flows are typically caused by natural terrain landslides triggered by intense rainfalls. If an incoming mountain torrent collapses a series of landslide dams, large debris flows can form in a very short period. Moreover, the torrent can amplify the scale of the debris flow in the flow direction. The catastrophic debris flows that occurred in Zhouqu, China, on 8 August 2010 were caused by intense rainfall and the upstream cascading failure of landslide dams along the gullies. In the wake of the incident, a field study was conducted to better understand the process of cascading landslide dam failures and the formation of debris flows. This paper looks at the geomorphic properties of the debris-flow gullies, estimates the peak flow discharges at different locations using three different methods, and analyzes the key modes (i.e., different landslide dam types and their combinations) of cascading landslide dam failures and their effect on the scale amplification of debris flows. The results show that five key modes in Luojiayu gully and two modes in Sanyanyu gully accounted for the scale amplification of downstream debris flows in the Zhouqu event. This study illustrates how the hazardous process of natural debris flows can begin several kilometers upstream as a complex cascade of geomorphic events (failure of landslide dams and erosion of the sloping bed) can scale to become catastrophic discharges. Neglecting recognition of these hazardous geomorphic and hydrodynamic processes may result in a high cost.

Published

2013

9. LIDAR monitoring of mass wasting processes: The Radicofani landslide, Province of Siena, Central Italy

Author

Marco Baldo, Daniele Giordan, Claudio Bicocchi, Giorgio Lollino, and Ugo Chiocchini

Subjects

Aerial survey, Mass movement, GPS, Pelites, Landslide, Mass wasting, Structural basin, LIDAR, DTM, Tectonics, Mudflow, Extensional tectonics, Geomorphology, Geology, Earth-Surface Processes

Abstract

The Radicofani Basin, stretching about 30 km NW–SE, is an intra-Central Apennine basin connected to Pliocene–Pleistocene extensional tectonics. It consists of an Early to Middle Pliocene succession including essentially shelf pelites. In the Radicofani area, province of Siena (Tuscany region), morphodynamic processes are very frequent with widespread badlands and rapidly evolving mudflows. In order to evaluate the general instability of the Radicofani area, geological and geomorphological surveys were carried out. The 1954, 1990 and 2003 aerial surveys allowed a comparison of the changes in the various morphological aspects of the study area, which suggested an increase in slope instability with time. A new complex translational landslide evolving into mudflows, activated during the winter of 2003, was monitored using an experimental system based on terrestrial LIDAR (Light Detection and Ranging) and GPS (Global Positioning System) technologies. This system allowed the monitoring of the morphologic and volumetric evolution of the landslide. A comparison of the monitoring data of October 2004, June 2005, May 2006 and May 2007 points out that the evolution is characterised by the sliding of displaced materials. A volume of about 1300 m 3 of materials was removed during the period 2004–2005, 300 m 3 for 2005–2006, and 400 m 3 for 2006–2007. The greater initial mass movement probably reflects a greater static imbalance during the early period of landslide movement and increased rainfall. Therefore, the proposed monitoring system methodology allows the numerical evaluation of the landslide morphological evolution and to validate the landslide evolution model based on geological and geomorphological field surveys.

Published

2009

10. Contrasting rainfall generated debris flows from adjacent watersheds at Forest Falls, southern California, USA

Author

Rachel M. Alvarez, Kelly R. Ruppert, Brett R. Goforth, and Douglas M. Morton

Subjects

Hydrology, education.field_of_study, Population, Fluvial, Landslide, Snow, Debris, Debris flow, Hyperconcentrated flow, Mudflow, education, Geomorphology, Geology, Earth-Surface Processes

Abstract

Debris flows are widespread and common in many steeply sloping areas of southern California. The San Bernardino Mountains community of Forest Falls is probably subject to the most frequently documented debris flows in southern California. Debris flows at Forest Falls are generated during short-duration high-intensity rains that mobilize surface material. Except for debris flows on two consecutive days in November 1965, all the documented historic debris flows have occurred during high-intensity summer rainfall, locally referred to as ‘monsoon’ or ‘cloudburst’ rains. Velocities of the moving debris range from about 5 km/h to about 90 km/h. Velocity of a moving flow appears to be essentially a function of the water content of the flow. Low velocity debris flows are characterized by steep snouts that, when stopped, have only small amounts of water draining from the flow. In marked contrast are high-velocity debris flows whose deposits more resemble fluvial deposits. In the Forest Falls area two adjacent drainage basins, Snow Creek and Rattlesnake Creek, have considerably different histories of debris flows. Snow Creek basin, with an area about three times as large as Rattlesnake Creek basin, has a well developed debris flow channel with broad levees. Most of the debris flows in Snow Creek have greater water content and attain higher velocities than those of Rattlesnake Creek. Most debris flows are in relative equilibrium with the geometry of the channel morphology. Exceptionally high-velocity flows, however, overshoot the channel walls at particularly tight channel curves. After overshooting the channel, the flows degrade the adjacent levee surface and remove trees and structures in the immediate path, before spreading out with decreasing velocity. As the velocity decreases the clasts in the debris flows pulverize the up-slope side of the trees and often imbed clasts in them. Debris flows in Rattlesnake Creek are relatively slow moving and commonly stop in the channel. After the channel is blocked, subsequent debris flows cut a new channel upstream from the blockage that results in the deposition of new debris-flow deposits on the lower part of the fan. Shifting the location of debris flows on the Rattlesnake Creek fan tends to prevent trees from becoming mature. Dense growths of conifer seedlings sprout in the spring on the late summer debris flow deposits. This repeated process results in stands of even-aged trees whose age records the age of the debris flows.

Published

2008

11. Alpine debris flows triggered by a 28 July 1999 thunderstorm in the central Front Range, Colorado

Author

Jonathan W. Godt and Jeffrey A. Coe

Subjects

Hydrology, geography, geography.geographical_feature_category, Bedrock, Front (oceanography), Landslide, Debris, Debris flow, Mudflow, Surface runoff, Geomorphology, Geology, Earth-Surface Processes, Colluvium

Abstract

On 28 July 1999, about 480 alpine debris flows were triggered by an afternoon thunderstorm along the Continental Divide in Clear Creek and Summit counties in the central Front Range of Colorado. The thunderstorm produced about 43 mm of rain in 4 h, 35 mm of which fell in the first 2 h. Several debris flows triggered by the storm impacted Interstate Highway 70, U.S. Highway 6, and the Arapahoe Basin ski area. We mapped the debris flows from color aerial photography and inspected many of them in the field. Three processes initiated debris flows. The first process initiated 11% of the debris flows and involved the mobilization of shallow landslides in thick, often well vegetated, colluvium. The second process, which was responsible for 79% of the flows, was the transport of material eroded from steep unvegetated hillslopes via a system of coalescing rills. The third, which has been termed the “firehose effect,” initiated 10% of the debris flows and occurred where overland flow became concentrated in steep bedrock channels and scoured debris from talus deposits and the heads of debris fans. These three processes initiated high on steep hillsides (> 30°) in catchments with small contributing areas (

Published

2007

12. Recent rainfall-induced landslides and debris flow in northern Taiwan

Author

Yi-Guan Chi, Hongey Chen, and Simon Dadson

Subjects

Hydrology, geography, geography.geographical_feature_category, Bedrock, Landslide classification, Pyroclastic rock, Landslide, Debris, Debris flow, Mudflow, Slope stability, Geomorphology, Geology, Earth-Surface Processes

Abstract

This paper discusses the factors initiating landslides and a large-scale debris flow in the Chonho area of Taipei County, northern Taiwan, which resulted from heavy rainfall during Typhoon Xangsane in November 2000. The morphology and triggering mechanism of the landslides and the debris flow were investigated using aerial photographs taken over the past 20 years, field measurement of channel cross-sections, laboratory assessment of slope material properties, and slope stability analysis. A large landslide that occurred in the source area was the initial source of material for the debris flow. The majority of the landslide debris entered the main stream, where it mixed with water and became a debris flow. Eroding the sidewalls of the stream, the debris flow entrained additional material and traveled downstream into Chonho Village. Our findings indicate that the November 2000 landslides and the debris flow were strongly influenced by the physical properties of the underlying pyroclastic substrate and the pattern of bedrock discontinuities within the valleys.

Published

2006

13. Processes and rate of retreat of the clay and sandstone sea cliffs of the northern Boulonnais (France)

Author

Guillaume Pierre, Université de Reims Champagne-Ardenne (URCA), Groupe d'Étude sur les Géomatériaux et Environnements Naturels, Anthropiques et Archéologiques - EA 3795 (GEGENAA), Université de Reims Champagne-Ardenne (URCA)-SFR Condorcet, Université de Reims Champagne-Ardenne (URCA)-Université de Picardie Jules Verne (UPJV)-Centre National de la Recherche Scientifique (CNRS)-Université de Reims Champagne-Ardenne (URCA)-Université de Picardie Jules Verne (UPJV)-Centre National de la Recherche Scientifique (CNRS)-Maison des Sciences Humaines de Champagne-Ardenne (MSH-URCA), and Université de Reims Champagne-Ardenne (URCA)-Université de Reims Champagne-Ardenne (URCA)

Subjects

Shore, geography, Plage, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Boulonnais, Coastal erosion, 010502 geochemistry & geophysics, 01 natural sciences, Debris, Cliff retreat, Mudflow, Shore platform, Cliff, Erosion, [SDU.STU.GM]Sciences of the Universe [physics]/Earth Sciences/Geomorphology, 14. Life underwater, Pebble, Sedimentary budget, Geomorphology, Geology, Argiles de Châtillon, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

International audience; Retreat of the clay and sandstone cliffs of the northern Boulonnais (France) has been quantified using stereophotogrammetry. The low retreat rate of this coastal strip-0.08 m/yr between 1939 and 2003-is far less than that encountered on chalk and clay-chalk cliffs of either side of the Channel, and even less than a previous estimate of 0.17 m/yr regularly quoted in management studies. The retreat rate is closely related to shore platform morphology and dynamics. The shore platform presents 1) a steeply sloping ramp due to the accumulation of flat calcareous megaclasts that reduce marine erosion; 2) upstanding bare platform surfaces, related to tectonic deformation; and 3) thick platform-beaches trapped in troughs. In all three cases, the reflective behaviour of the nearshore protects the cliff foot from the incoming waves. Two critical eroding segments are the result of changes in the platform sedimentary budget. Around Cran Poulet, and between Plage de la Sirène and Pointe de la Courte Dune, the retreat rate is up to 0.25 and 0.15 m/yr, respectively. At Cran Poulet, recession has been facilitated by the extraction of pebble for more than half a century, whereas erosion of the beach at la Sirène is probably linked to severe erosion of the coastline in the adjacent Wissant Bay. Mass movements on the cliff face are essentially shallow-seated translational slides along with small debris falls and mudflows. The instability of the Argiles de Châtillon is greatly diminished by their sandy and silty texture and by the presence of interstratified solid shelly limestone beds that allow steep slopes to develop in rather weak material. The dvertical erosion antecedentT is the erosional mode of the cliff, and its reduced efficiency explains the slow recession of the cliff. This study will help to determine the long term evolution of the Boulonnais coast.

Published

2006

14. Conceptual model of sediment processes in the upper Yuba River watershed, Sierra Nevada, CA

Author

Charles N. Alpers, S. M. Yarnell, Jennifer A. Curtis, and Lorraine E. Flint

Subjects

Hydrology, geography, geography.geographical_feature_category, Mudflow, Tributary, Drainage basin, Erosion, Hydraulic mining, Sediment, Mass wasting, STREAMS, Geology, Earth-Surface Processes

Abstract

This study examines the development of a conceptual model of sediment processes in the upper Yuba River watershed; and we hypothesize how components of the conceptual model may be spatially distributed using a geographical information system (GIS). The conceptual model illustrates key processes controlling sediment dynamics in the upper Yuba River watershed and was tested and revised using field measurements, aerial photography, and low elevation videography. Field reconnaissance included mass wasting and channel storage inventories, assessment of annual channel change in upland tributaries, and evaluation of the relative importance of sediment sources and transport processes. Hillslope erosion rates throughout the study area are relatively low when compared to more rapidly eroding landscapes such as the Pacific Northwest and notable hillslope sediment sources include highly erodible andesitic mudflows, serpentinized ultramafics, and unvegetated hydraulic mine pits. Mass wasting dominates surface erosion on the hillslopes; however, erosion of stored channel sediment is the primary contributor to annual sediment yield. We used GIS to spatially distribute the components of the conceptual model and created hillslope erosion potential and channel storage models. The GIS models exemplify the conceptual model in that landscapes with low potential evapotranspiration, sparse vegetation, steep slopes, erodible geology and soils, and high road densities display the greatest hillslope erosion potential and channel storage increases with increasing stream order. In-channel storage in upland tributaries impacted by hydraulic mining is an exception. Reworking of stored hydraulic mining sediment in low-order tributaries continues to elevate upper Yuba River sediment yields. Finally, we propose that spatially distributing the components of a conceptual model in a GIS framework provides a guide for developing more detailed sediment budgets or numerical models making it an inexpensive way to develop a roadmap for understanding sediment dynamics at a watershed scale. Published by Elsevier B.V.

Published

2005

15. Slope failures in the Blue Nile basin, as seen from landscape evolution perspective

Author

Lulseged Ayalew and Hiromitsu Yamagishi

Subjects

Slump, geography, geography.geographical_feature_category, Rockfall, Landform, Nile basin, Mudflow, Landslide, Digital elevation model, Geomorphology, Geology, Earth-Surface Processes, River incision

Abstract

The Blue Nile basin is severely affected by slope failures, and the characteristics of its deep gorges and rugged valley walls called for a study on the relationships between topography and the process of landsliding and rock falling. Work was commenced with the conception of nine types of landforms on the basis of a one-to-one combination of lateral and vertical slope profiles and thence the determination of the effect of these landforms on the occurrence of slope failures. Observations showed that topographic surfaces with concave lateral profiles shelter mudflows and some retrogressive rotational slumps while slopes characterized by planar lateral profiles are sites mainly for translational slides. Landslides are rare in convex-shaped slopes but when they occur, they are big and deep-seated. As an effort to understand the significant contributions of landslides and rock falls to landscape development, direct and indirect methods are employed. Direct methods are based on quantitative relationships between the volume of material that had been removed from the area and the amount that could, in principle, be taken away based on available erosion rates. Indirect methods used the nature of river incision and the effect of the present-day landslides on the landscape. In general, discrepancy in calculated figures in the first, and the overall drop and form of the Abay River gorge coupled with the observed landslide-caused landform changes in the second, led us to deduce that slope failures were part of the mega-forces that shaped the entire Blue Nile basin, and in fact, played the dominant role in landscape evolution.

Published

2004

16. Debris flows in Glacier National Park, Montana: geomorphology and hazards

Author

Forrest Wilkerson and Ginger L. Schmid

Subjects

geography, geography.geographical_feature_category, Mudflow, Antecedent moisture, Glacier, Landslide, Fault scarp, Debris, Geomorphology, Geology, Channel (geography), Earth-Surface Processes, Debris flow

Abstract

Debris flows are one of the many active slope-forming processes within Glacier National Park, Montana. Most debris flow landforms exhibit classic morphology with a distinct failure scarp, incised channel, channel levees, and toe deposits that often develop a lobate form. The Precambrian metasediments that dominate Glacier National Park's geology weather into angular clasts that range in size from platy gravels to boulders. Classic debris flows occur in areas where the topographic expression provides a debris source from cliff faces and an accumulation of regolith, often in the form of talus slopes. Many of these debris flows have long runout zones and can travel many hundreds of meters. Often they cross hiking trails or roads, including the main east–west highway, Going-to-the-Sun Road. Debris flows impacting the road have resulted in several near fatalities, and hikers have been forced to cross active debris flows to reach safe ground. The magnitude of debris flows varies between high magnitude channel incising events and low magnitude channel filling and/or reworking events. The frequency of debris flow events is irregular and appears to be controlled by the hydrology of triggering storms and antecedent moisture conditions, not by the debris supply. As a result, debris flow magnitude is not a function of frequency, but is more closely related to the characteristics of antecedent conditions and individual storms.

Published

2003

17. Geologic factors contributing to landslide generation in a pyroclastic area: August 1998 Nishigo Village, Japan

Author

Masahiro Chigira

Subjects

Igneous rock, Mudflow, Landslide classification, Pumice, Geochemistry, Pyroclastic rock, Landslide, Scoria, Geomorphology, Geology, Earth-Surface Processes, Colluvium

Abstract

Vertical contrasts in permeability, particularly where permeable surface materials overlie impermeable materials that prohibit the downward infiltration of groundwater, concentrate the groundwater and become an important focus of landslides that are triggered by intense rainfall. Just such a hydrogeological structure is present within the pyroclastics in Nishigo Village in Fukushima Prefecture, Japan, where intense rainfall of 1200 mm in 6 days generated more than 1000 landslides in August 1998. Three types of landslides occurred. The first type occurred along the edges of small plateaus, where horizontal beds of permeable ash, scoria, and pumice overlie impermeable mudflow deposits consisting of tuffaceous fines and andesite blocks, and massive, weakly consolidated ignimbrites. The rainfall on the plateaus infiltrated downward first, then laterally within the permeable beds, finally gushing out at the plateau edges and triggering landslides. The second type of landslide occurred where weathered tuff of the same ignimbrite was present with a slip surface at the base of the heavily weathered zone. Within this heavily weathered zone, the tuff exfoliated into thin weak plates running parallel to the slope surface. The third type of landslide involved failure of colluvium or ash that filled hollows. This type occurred as a result of subsurface erosion caused by the groundwater infiltrating the superficial beds above the impermeable tuff.

Published

2002

18. Reconstructing recent landslide activity in relation to rainfall in the Llobregat River basin, Eastern Pyrenees, Spain

Author

José Moya and Jordi Corominas

Subjects

Hydrology, geography, geography.geographical_feature_category, Mudflow, Drainage basin, Dendrochronology, Landslide, Precipitation, Structural basin, Debris, Geology, Earth-Surface Processes, Colluvium

Abstract

A chronology of recent landslides in the upper basin of the Llobregat River, Eastern Pyrenees, has been reconstructed from technical reports, field reconnaissance and dendrogeomorphological analysis. The precipitation conditions responsible for triggering and reactivating landslides have been deduced by analysis of rainfall records from two rain gauges located in the area. Two different rainfall patterns relate to landslide occurrence: (i) Without antecedent rainfall, high intensity and short duration rains trigger mostly debris flows and shallow slides developed in colluvium and weathered rocks. A rainfall threshold of around 190 mm in 24 h initiates failures whereas more than 300 mm in 24–48 h are needed to cause widespread shallow landsliding; (ii) with antecedent rain, moderate intensity precipitation of at least, 40 mm in 24 h reactivates mudslides and both rotational and translational slides affecting clayey and silty–clayey formations. In this case, several weeks and 200 mm of precipitation are needed to cause landslide reactivation. Dendrochronological analysis shows that landslide activity in the Eastern Pyrenees was relatively low between 1926 and 1959 but has since increased significantly with reactivation now occurring about every 3 years.

Published

1999

19. Cosmogenic ages and frequency of late Holocene debris flows from Prospect Canyon, Grand Canyon, USA

Author

Robert J. Poreda, Theodore S. Melis, Alan D. Rigby, Robert H. Webb, and Thure E. Cerling

Subjects

Canyon, Paleontology, geography, geography.geographical_feature_category, Aggradation, Mudflow, Tributary, Quaternary, Debris, Geology, Holocene, Earth-Surface Processes, Debris flow

Abstract

Lava Falls Rapid, which was created and is maintained by debris flows from Prospect Canyon, is the most formidable reach of whitewater on the Colorado River in Grand Canyon and is one of the most famous rapids in the world. Debris flows enter the Colorado River at tributary junctures, creating rapids. The frequency of debris flows is an important consideration when management of regulated rivers involves maintenance of channel morphology. We used cosmogenic 3 He , 14 C , and historical photographs to date 12 late Holocene and historic debris flows from Prospect Canyon. The highest and oldest deposits from debris flows on the debris fan yielded a 3 He date of about 3 ka, which indicates predominately late Holocene aggradation of one of the largest debris fans in Grand Canyon. The deposit, which has a 25-m escarpment caused by river reworking, crossed the Colorado River and raised its base level by 30 m for an indeterminate although likely short period. We mapped depositional surfaces of 11 debris flows that occurred after 3 ka. Two deposits inset against the highest deposit yielded 3 He ages of about 2.2 ka, and at least two others followed shortly afterwards. At least one of these debris flows also dammed the Colorado River. The most recent prehistoric debris flow occurred no more than 0.5 ka. The largest historic debris flow, which constricted the river by 80%, occurred in 1939. Five other debris flows occurred after 1939; these debris flows constricted the Colorado River by 35–80%. Assuming the depositional volumes of late Holocene debris flows can be modeled using a lognormal distribution, we calculated recurrence intervals of 15 to more than 2000 years for debris flows from Prospect Canyon.

Published

1999

20. The landslide hazard in the Himalayas: geological control and human action

Author

John Gerrard

Subjects

geography, geography.geographical_feature_category, Phyllite, Geochemistry, Landslide, Hazard analysis, Debris, Rockfall, Slope stability, Mudflow, Geomorphology, Geology, Earth-Surface Processes, Gneiss

Abstract

Mountains are high-energy environments characterised by instability and variability. Much of this instability is the result of a variety of landsliding processes; mudflows, rockfalls and debris slides/avalanches being especially important. This landsliding constitutes a major hazard in the Himalayas. Early work has suggested that certain rock types are more predisposed to failure than others. It also seems possible that specific types of failure are related to certain rock types and properties. This analysis suggests that these relationships can be employed in a hazard assessment. Phyllite rocks are the most susceptible to landsliding followed by shales, schists, poorly cemented sandstones, gneiss, granites and quartzite. This order is also appropriate for slope failures within weathered material although weathered gneiss appears to be more susceptible to rill and gully erosion. Clearly rock type exerts a major influence on landsliding, but assessing the role of rock type in comparison to the effect of human activity is difficult. Human activity is often influenced by the nature of slopes, including the type and depth of material on the slopes. As these are affected by rock type, it is difficult to differentiate the contributing factors. Because of this it would be dangerous to assume that landsliding in the Himalayas can be completely explained and predicted by the nature of the rock type.

Published

1994

21. The geomorphology of some debris flows in the southern Sierra Nevada, California

Author

Jerome V. DeGraff

Subjects

geography.river, Hydrology, geography, geography.geographical_feature_category, Bedrock, Landslide, Storm, Kings River, Debris, Debris flow, Mudflow, San Joaquin, Geomorphology, Geology, Earth-Surface Processes

Abstract

Debris flows are one of the natural hazards present in the southern Sierra Nevada of California. Historic debris flow activity is documented at a USDA Forest Servuce research facility in the Kings River drainage related to a 1937 storm event. No subsequent study of this phenomenon was undertaken until 1982. Observations of debris flows over the succeeding 10 years offer an initial assessment of the physical geomorphology of debris flows in this area. This information provides a starting point for future efforts to avoid or limit the effect of this natural hazard. Observations were made in the Tuolomne, Merced, San Joaquin, and Kings River drainages. Of the twenty-six debris flows observed, six were examined in detail to provide specific data on this phenomenon. Triggering events for debris flows in the southern Sierra Nevada include intense rainfall, rain-on-snow storms, and seasonal melting of heavy snowpacks. Movement typically occurs at depths between 0.3 and 5 m below ground surface. This is representative of depths for the three interfaces associated with initiation of movement: (1) at the base of the root zone, (2) at the contact of well-weathered and less-weathered soil, and (3) at the contact between soil and unweathered bedrock. Measurement of debris flow velocity based on indirect methods found values ranging from 2.6 m/s to 7.2 m/s (9 km/h to 26 km/h). Recurrence intervals based on radiocarbon dates are between 425 and 500 years BP. Roads and other land use investments have suffered damage from debris flow activity during the 1982 to 1993 period. Stump Springs road in the San Joaquin river drainage required US$1.4 million to repair damage primarily from 1982 debris flows. The threat to life arising from debris flows is illustrated by the consequences of vegetation losses from wildfire near El Portal, California. The projected population growth with associated increased infrastructure raises concern for greater impacts from future debris flow occurrence in the southern Sierra Nevada.

Published

1994

22. Debris flows as geomorphic agents in the Huachuca Mountains of southeastern Arizona

Author

Philip P. Pearthree and Ellen Wohl

Subjects

Hydrology, geography, geography.geographical_feature_category, Bedrock, Alluvial fan, Landslide, Debris, Debris flow, Hyperconcentrated flow, Mudflow, Tributary, Geomorphology, Geology, Earth-Surface Processes

Abstract

Numerous debris flows occurred in the Huachuca Mountains of southeastern Arizona during the summer rainy season of 1988 in areas that were burned by a forest fire earlier in the summer. Debris flows occurred following a major forest fire in 1977 as well, suggesting a causal link between fires and debris flows. Abundant evidence of older debris flows preserved along channels and in mountain front fans indicates that debris flows have occurred repeteadly during the late Quaternary in this environment. Soil development in sequences of debris-flow deposits indicates that debris flows probably recur over time intervals of several hundred to a thousand years in individual drainage basins in the study area. Surface runoff in the steep drainage basins of the Huachuca Mountains is greatly enhanced following forest fires, as the hillslopes are denuded of their vegetative cover. Water and sediment eroded from the hillslope regolith are rapidly introduced into the upper reaches of tributary channels by widespread rilling and slope wash during rainfall events. This influx of water and sediment destabilizes regolith previously accumulated in the channel, triggering debris flows that scour the channel to bedrock in the upper reaches. Following a debris flow, the scoured, trapezoidally-shaped channel gradually assumes a swale shape and the percentage of exposed bedrock declines, as material is introduced from the slopes. Debris flows do a tremendous amount of work in a very short time, however, and are the major channel-forming events. Where the tributary channels enter larger, trunk channels, the debris flows serve as the main source of very coarse sediment. The local slope and coarse particle distribution of the trunk channel depend on the competence of water flows in the channel to transport the material introduced by debris flows. Where the smaller channels drain directly to the mountain front, debris flows create extensive alluvial fans which dominate the morphology of the basin-range boundary. Time intervals between debris flows in the drainage basins of the Huachuca Mountains are probably controlled by complex interactions among climate, forest fires and slope processes. Fires destroy the protective vegetation that stabilizes the upper catchment slopes and inhibits erosion. However, not every fire that burns a catchment causes debris flows, because sufficient weathered material must accumulate in the upper channel reaches to initiate a large debris flow. If such accumulation has not occurred, the material introduced to a channel following a forest fire will move only a short distance down the channel. Thus, the episodic nature of debris flows probably depends on rates of slope weathering and erosion, which are in turn controlled by climate, both directly and through vegetation and forest fires.

Published

1991