Your search keyword '"Brardinoni F"' showing total 6 results

1. Rock-avalanche geomorphological and hydrological impact on an alpine watershed

Author

Frattini, P., primary, Riva, F., additional, Crosta, G.B., additional, Scotti, R., additional, Greggio, L., additional, Brardinoni, F., additional, and Fusi, N., additional

Published

2016

2. Effects of sediment mixing on 10Be concentrations in the Zielbach catchment, central-eastern Italian Alps

Author

Savi, S., primary, Norton, K., additional, Picotti, V., additional, Brardinoni, F., additional, Akçar, N., additional, Kubik, P.W., additional, Delunel, R., additional, and Schlunegger, F., additional

Published

2014

3. Channel morphology and bed-load yield in fluvial, formerly-glaciated headwater streams of the Columbia Mountains, Canada

Author

Green, K.C., primary, Brardinoni, F., additional, and Alila, Y., additional

Published

2013

4. Effects of sediment mixing on 10Be concentrations in the Zielbach catchment, central-eastern Italian Alps

Author

Peter W. Kubik, Romain Delunel, Kevin Norton, Sara Savi, Fritz Schlunegger, Francesco Brardinoni, Vincenzo Picotti, Naki Akçar, Savi, S, Norton, K, Picotti, V, Brardinoni, F, Ackar, N, Kubik, P, Delunel, R, Schlunegger, F, Savi S, Norton K, Picotti V, Brardinoni F, Ackar N, Kubik PW, Delunel R, and Schlunegger F

Subjects

Provenance, Mass-wasting processe, Spatial mixing, Temporal mixing, Mass-wasting processes, Basin-wide erosion rate, Cosmogenic nuclides, Südtirol, 010504 meteorology & atmospheric sciences, Stratigraphy, GEO/04 - GEOGRAFIA FISICA E GEOMORFOLOGIA, STREAMS, 010502 geochemistry & geophysics, 01 natural sciences, Downhill creep, Cosmogenic nuclide, Basin-wide erosion rate, Tributary, Earth and Planetary Sciences (miscellaneous), Spatial mixing, Mixing (physics), 0105 earth and related environmental sciences, Hydrology, geography, geography.geographical_feature_category, Südtirol, Sediment, Geology, 15. Life on land, 13. Climate action, Erosion, Temporal mixing

Abstract

Basin-wide erosion rates can be determined through the analysis of in situ-produced cosmogenic nu- clides. In transient landscapes, and particularly in mountain catchments, erosion and transport processes are often highly variable and consequently the calculated erosion rates can be biased. This can be due to sediment pulses and poor mixing of sediment in the stream channels. The mixing of alluvial sediment is one of the principle conditions that need to be verified in order to have reliable results. In this paper we perform a field-based test of the extent of sediment mixing for a w42 km2 catchment in the Alps using concentrations of river-born 10Be. We use this technique to assess the mechanisms and the spatio- temporal scales for the mixing of sediment derived from hillslopes and tributary channels. The results show that sediment provenance and transport, and mixing processes have a substantial impact on the 10Be concentrations downstream of the confluence between streams and tributary channels. We also illustrate that the extent of mixing significantly depends on: the sizes of the catchments involved, the magnitude of the sediment delivery processes, the downstream distance of a sample site after a con- fluence, and the time since the event occurred. In particular, continuous soil creep and shallow land- sliding supply high 10Be concentration material from the hillslope, congruently increasing the 10Be concentrations in the alluvial sediment. Contrariwise, a high frequency of mass-wasting processes or the occurrence of sporadic but large-magnitude events results in the supply of low-concentration sediment that lowers the cosmogenic nuclide concentration in the channels. The predominance of mass-wasting processes in a catchment can cause a strong bias in detrital cosmogenic nuclide concentrations, and therefore calculated erosion rates may be significantly over- or underestimated. Accordingly, it is important to sample as close as possible to the return-period of large-size sediment input events. This will lead to an erosion rate representative of the “mass-wasting signal” in case of generally high-frequency events, or the “background signal” when the event is sporadic. Our results suggest that a careful con- sideration of the extent of mixing of alluvial sediment is of primary importance for the correct estimation of 10Be-based erosion rates in mountain catchments, and likewise, that erosion rates have to be inter- preted cautiously when the mixing conditions are unknown or mixing has not been achieved. Basin-wide erosion rates can be determined through the analysis of in situ-produced cosmogenic nuclides. In transient landscapes, and particularly in mountain catchments, erosion and transport processes are often highly variable and consequently the calculated erosion rates can be biased. This can be due to sediment pulses and poor mixing of sediment in the stream channels. The mixing of alluvial sediment is one of the principle conditions that need to be verified in order to have reliable results. In this paper we perform a field-based test of the extent of sediment mixing for a w42 km2 catchment in the Alps using concentrations of river-born 10Be. We use this technique to assess the mechanisms and the spatiotemporal scales for the mixing of sediment derived from hillslopes and tributary channels. The results show that sediment provenance and transport, and mixing processes have a substantial impact on the 10Be concentrations downstream of the confluence between streams and tributary channels. We also illustrate that the extent of mixing significantly depends on: the sizes of the catchments involved, the magnitude of the sediment delivery processes, the downstream distance of a sample site after a confluence, and the time since the event occurred. In particular, continuous soil creep and shallow landsliding supply high 10Be concentration material from the hillslope, congruently increasing the 10Be concentrations in the alluvial sediment. Contrariwise, a high frequency of mass-wasting processes or the occurrence of sporadic but large-magnitude events results in the supply of low-concentration sediment that lowers the cosmogenic nuclide concentration in the channels. The predominance of mass-wasting processes in a catchment can cause a strong bias in detrital cosmogenic nuclide concentrations, and therefore calculated erosion rates may be significantly over- or underestimated. Accordingly, it is important to sample as close as possible to the return-period of large-size sediment input events. This will lead to an erosion rate representative of the “mass-wasting signal” in case of generally high-frequency events, or the “background signal” when the event is sporadic. Our results suggest that a careful consideration of the extent of mixing of alluvial sediment is of primary importance for the correct estimation of 10Be-based erosion rates in mountain catchments, and likewise, that erosion rates have to be interpreted cautiously when the mixing conditions are unknown or mixing has not been achieved.

Published

2014

5. Colluvial sediment dynamics in mountain drainage basins

Author

Denny Maynard, Marwan A. Hassan, Terry Rollerson, Francesco Brardinoni, Brardinoni F, Hassan M, Rollerson T, Maynard T, Brardinoni, F, Hassan, M, Rollerson, T, and Maynard, T

Subjects

landslide, glaciated landscape, 010504 meteorology & atmospheric sciences, glaciated landscapes,landslides, colluvial channels, sediment dynamics, spatial scales, GEO/04 - GEOGRAFIA FISICA E GEOMORFOLOGIA, Drainage basin, Fluvial, 010502 geochemistry & geophysics, 01 natural sciences, Geochemistry and Petrology, sediment dynamic, colluvial channel, Earth and Planetary Sciences (miscellaneous), Glacial period, Geomorphology, 0105 earth and related environmental sciences, Colluvium, Hydrology, geography, geography.geographical_feature_category, spatial scales, Sediment, Last Glacial Maximum, Landslide, 15. Life on land, Geophysics, Space and Planetary Science, Alluvium, Geology

Abstract

Colluvial sediment dynamics are examined using a 70-year landslide inventory in formerly glaciated mountain drainage basins of coastal British Columbia, Canada. Landslide sediment transfer is documented by identifying landslide types, and by characterizing preferential sites of landslide initiation, delivery, and storage across spatial scales. Data analysis reveals that open-slope landslides delivering material to seasonal or perennial channels and fluvial terraces are the dominant mechanisms of sediment transfer. This finding suggests high instability of the low-order channel network and its ongoing re-organization (degradation) after generalized sediment recharge occurred in the last glacial maximum. In the study period, landslide activity across the landscape has generated net degradation on planar slopes and first-order colluvial channels, whereas unchannelled valleys, higher-order colluvial channels and alluvial channels have accumulated material. The scaling relation of the landslide sediment yield appears to be controlled by the spatial arrangement of the relict glacial macro-forms. Landslide yield is highest in unchannelled topography, decreases at the scale of channel initiation (Ad~0.002 km2), and remains constant for drainage areas where length scales of cirque/valley walls and hanging valley floors overlap (0.002bAdb0.06). Injections of landslide material start declining consistently beyond areas larger than 0.6 km2 (the scale of relict glacial trough initiation), where fluvial environments become increasingly disconnected from landslide inputs. Cumulative yield indicates that colluvial sediment redistribution is limited to small basins; specifically, 90% of the colluvial load is released at scales smaller than about 0.6 km2

Published

2009

6. Landslide inventory in a rugged forested watershed: a comparison between air-photo and field survey data

Author

Francesco Brardinoni, Olav Slaymaker, Marwan A. Hassan, Brardinoni, F, Slaymaker, O, and Hassan, M

Subjects

Hydrology, education.field_of_study, Geographic information system, business.industry, Population, Terrain, Landslide, Structural basin, Aerial photography, Slope stability, Landslide identification, Air-photo interpretation, Interbasin variability, Forested terrain, Coastal British Columbia, business, education, Drainage density, Geology, Earth-Surface Processes

Abstract

Landslide inventories are routinely compiled by means of aerial photo interpretation (API). When examining photo pairs, the forest canopy (notably in old-growth forest) hides a population of "not visible" landslides. In the present study, we attempt to estimate how important is the contribution of landslides not detectable from aerial photographs to the global mass of sediment production from mass failures on forested terrain of the Capilano basin, coastal British Columbia. API was coupled with intensive fieldwork for identification and measurement of all landslides. A 30-year framework was adopted. We show that "not visible" landslides can represent up to 85% of the total number of failures and account for 30% of the volume of debris mobilised. Such percentages display high sub-basin variability with rates of sediment production varying by one order of magnitude between two sub-basins of the study area. This is explained qualitatively by GIS-based analysis of slope frequency distributions, drainage density, and spatial distribution of surficial materials. Such observations find further support in the definitions of transport-limited and supply-limited basins. As a practical consideration to land managers, we envisage that supplementary fieldwork for landslide identification is mandatory in transport-limited systems only. Fieldwork has demonstrated that gully-related failures have a greater importance than one could expect from API. © 2002 Elsevier Science B.V. All rights reserved.

Published

2003