Your search keyword '"Guénolé Choné"' showing total 8 results

1. Comparative analysis of local and large-scale approaches to floodplain mapping: a case study of the Chaudière River

Author

Mohammed Amine Bessar, Guénolé Choné, P. Matte, Pascale M. Biron, François Anctil, A. Lavoie, and Thomas Buffin-Bélanger

Subjects

geography, geography.geographical_feature_category, Floodplain, Hydraulic engineering, Scale (social sciences), HEC-RAS, Future climate, Natural disaster, Environmental planning, Water Science and Technology

Abstract

Floods are among natural disasters that increasingly threaten society, especially with current and future climate change trends. Several tools have been developed to help planners manage the risks ...

Published

2021

2. Development of a mapping approach encompassing most fluvial processes: Lessons learned from the freedom space for rivers concept in Quebec (Canada)

Author

Thomas Buffin-Bélanger, Simon Massé, William Massey, Pascale M. Biron, Sylvio Demers, Guénolé Choné, and Clément Besnard

Subjects

geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Flood myth, business.industry, Hydrogeomorphology, Flooding (psychology), Environmental resource management, 0207 environmental engineering, Alluvial fan, Fluvial, 02 engineering and technology, 15. Life on land, 01 natural sciences, 6. Clean water, Erosion, Environmental Chemistry, 020701 environmental engineering, Digital elevation model, business, Geology, Channel (geography), 0105 earth and related environmental sciences, General Environmental Science, Water Science and Technology

Abstract

The consensus around the need for a shift in river management approaches to include more natural processes is steadily growing amongst scientists, practitioners, and governmental agencies. The freedom space for rivers concept promotes the delineation of a single space that integrates multiple fluvial dynamics such as floods, lateral migration, channel avulsions, and riparian wetlands connectivity. The objective of this research is to assess the validity of the hydrogeomorphological approach to delineate the freedom space for an extensive sampling of river reaches, covering 167 km, in contrasting watersheds in Quebec (Canada). Comparative analysis was conducted on the relative importance of erosion and flood processes on the freedom space delineation for various fluvial types. Semiautomated tools based on light detection and ranging (LiDAR) digital elevation models were also tested on an additional 274 km of watercourses to facilitate freedom space mapping over extensive zones and for highly dynamics environments such as alluvial fans. In the studied reaches, flood and erosion processes occur respectively, on average, in a space equivalent to 2.6 and 20.6 channel widths. In unconfined landscapes, flood processes represent an area up to almost four times the area of erosion processes expected in a 50‐year period. In partly confined and confined environments, erosion processes are more likely to exceed flooding zone, and therefore need to be integrated in the mapping. This study helps better determine the conditions for which the full methodology of freedom space mapping is required or where semiautomated methods can be used. It provides useful guidelines for the implementation of the freedom space approach.

Published

2020

3. An assessment of <scp>large‐scale</scp> flood modelling based on <scp>LiDAR</scp> data

Author

Guénolé Choné, Iulia Mazgareanu, Christopher C. Sampson, Pascale M. Biron, Jeffrey Neal, and Thomas Buffin-Bélanger

Subjects

010504 meteorology & atmospheric sciences, Scale (ratio), Flood myth, 0207 environmental engineering, Environmental science, Lidar data, 02 engineering and technology, 020701 environmental engineering, 01 natural sciences, 0105 earth and related environmental sciences, Water Science and Technology, Water level, Remote sensing

Published

2021

4. Impacts of river bank stabilization using riprap on fish habitat in two contrasting environments

Author

William Massey, Pascale M. Biron, and Guénolé Choné

Subjects

0106 biological sciences, Hydrology, geography, geography.geographical_feature_category, 010604 marine biology & hydrobiology, 0208 environmental biotechnology, Geography, Planning and Development, Fluvial, 02 engineering and technology, STREAMS, 15. Life on land, 01 natural sciences, Debris, 6. Clean water, 020801 environmental engineering, Macrophyte, Habitat, Earth and Planetary Sciences (miscellaneous), Environmental science, Bank, Riprap, Earth-Surface Processes, Riparian zone

Abstract

Riverbank stabilization using rock riprap is commonly used for protecting road and bridge structures from fluvial erosion. However, little is known about how streams adjust to such perturbation or how this can affect fish habitat in different fluvial environments, particularly for non-salmonid species in small streams. The objective of this study is to assess impacts of riprap on fish habitat quantity and quality through a pairwise comparison of 27 stabilized and non-stabilized stream reaches in two physiographic regions, the Saint Lawrence Lowlands and the Appalachian highlands of Monteregie-Est (Quebec, Canada). Both quantitative (Hydro-morphological Index of Diversity, HMID) and qualitative (Qualitative Habitat Evaluation Index, QHEI) fish habitat assessment techniques are applied in order to compare results between methods. For each stream reach depth and velocity were measured to calculate HMID. In-stream cover (woody debris, overhanging vegetation, undercut banks, aquatic macrophytes) and habitat units (pools, riffles, runs, glides) were also documented and used to determine QHEI. Results show that overall bank stabilization using riprap at bridge and stream crossings alters fish habitat characteristics. Loss of in-stream covers and riparian vegetation lower QHEI scores at stabilized reaches, especially in more pristine Appalachian streams, but has less impact on already altered straightened Lowlands streams. In this latter context, some positive alterations of fish habitat were observed in riprapped reaches due to the coarsening of the substrate and an induced increase of slope. The two metrics (HMID and QHEI) revealed similar differences between stabilized and non-stabilized sites for Lowlands sites, but their level of agreement was much less in the Appalachian streams, suggesting caution when interpreting habitat quality results based on a single metric. Copyright © 2016 John Wiley & Sons, Ltd.

Published

2016

5. Freedom space for rivers: An economically viable river management concept in a changing climate

Author

Sylvio Demers, Pascale M. Biron, Guénolé Choné, Claude Desjarlais, Thomas Buffin-Bélanger, Joanna Eyquem, Marie-Audray Ouellet, Taylor Olsen, Marie Larocque, and Claude-André Cloutier

Subjects

Hydrology, Cost–benefit analysis, business.industry, Hydrogeomorphology, Environmental resource management, Flooding (psychology), Space (commercial competition), Flood stage, Ecosystem services, Agriculture, River management, business, Geology, Earth-Surface Processes

Abstract

The freedom space concept applies hydrogeomorphic principles to delineate zones that are either frequently flooded or actively eroding, or that include riparian wetlands. Freedom space limits mapped for three rivers in southern Quebec (Canada) were assessed to determine whether they would still be valid under a future climate using a sensitivity analysis approach with numerical models predicting mobility of meanders (RVRMeander) and flood stage (HEC-RAS). The freedom space limits were also used in a cost–benefit analysis over a 50-year period where costs consist of loss or limitations to the right of farming and construction in this zone, whereas benefits are avoided costs for existing or future bank stabilization structures and avoided costs of flooding in agricultural areas. The economic value of ecosystem services provided by riparian wetlands and increased buffer zones within the freedom space were also included in the analysis. Results show that freedom space limits would be robust in future climate, and show net present values ranging from CDN$0.7 to $3.7 million for the three rivers, with ratios of benefits over costs ranging between 1.5:1 and 4.8:1. River management based on freedom space is thus beneficial for society over a 50-year period.

Published

2015

6. Assessing the Relationship Between River Mobility and Habitat

Author

Guénolé Choné and Pascale M. Biron

Subjects

Hydrology, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Floodplain, 0208 environmental biotechnology, 02 engineering and technology, Sinuosity, 15. Life on land, 01 natural sciences, 020801 environmental engineering, Habitat, 13. Climate action, Erosion, Environmental Chemistry, Environmental science, Digital elevation model, Bank erosion, Channel (geography), 0105 earth and related environmental sciences, General Environmental Science, Water Science and Technology, Riparian zone

Abstract

Human interventions that limit channel mobility such as bank stabilization are frequent in riparian zones in urban or agricultural environments. This is potentially problematic because channel mobility is an important geomorphological and ecological agent that structures natural instream and riparian ecosystems. This study aims to (1) quantify the relationship between mobility and three types of habitat-related features, namely bars, oxbow lakes and log jams, for a 54-km-long reach of the Yamaska Sud-Est River (Quebec, Canada), which runs from the forested Appalachian Mountains to the agricultural St-Lawrence lowlands, and (2) evaluate the impact of human interventions and geomorphological characteristics on these three features. Channel mobility was measured from historical aerial photos for the period 1950–2009. A combination of high-resolution aerial photos, LiDAR digital elevation model, and field observations was used to measure and map sediment bars, oxbow lakes and log jams, as well as several geomorphological characteristics (channel width, slope, sinuosity and floodplain width). A strong link between the mobility and the presence of habitat features is revealed, but local geomorphological contexts result in different mobility patterns responsible for specific habitats. Floodplain to channel width ratio appears as the best geomorphological factor predicting habitat diversity. Human intervention, mostly through bank stabilization, also appears to be a key factor limiting mobility and its related habitats. These results highlight the importance of defining a protected mobility corridor along rivers where geomorphic processes such as bank erosion can freely occur, as it is an essential process that should be integrated in land use planning and river management. Copyright © 2015 John Wiley & Sons, Ltd.

Published

2015

7. Improvement of streams hydro-geomorphological assessment using LiDAR DEMs

Author

Taylor Olsen, Pascale M. Biron, Thomas Buffin-Bélanger, Guénolé Choné, and Sylvio Demers

Subjects

Hydrology, geography, Geographic information system, geography.geographical_feature_category, business.industry, Geography, Planning and Development, Elevation, Lidar, Earth and Planetary Sciences (miscellaneous), Environmental science, Spatial variability, Digital elevation model, business, Stream power, Channel (geography), Bank erosion, Earth-Surface Processes, Remote sensing

Abstract

Hydro-geomorphological assessments are an essential component for riverine management plans. They usually require costly and time-consuming field surveys to characterize the spatial variability of key variables such as flow depth, width, discharge, water surface slope, grain size and unit stream power throughout the river corridor. The objective of this research is to develop automated tools for hydro-geomorphological assessments using high-resolution LiDAR digital elevation models (DEMs). More specifically, this paper aims at developing geographic information system (GIS) tools to extract channel slope, width and discharge from 1 m-resolution LiDAR DEMs to estimate the spatial distribution of unit stream power in two contrasted watersheds in Quebec: a small agricultural stream (Des Feves River) and a large gravel-bed river (Matane River). For slope, the centreline extracted from the raw LiDAR DEM was resampled at a coarser resolution using the minimum elevation value. The channel width extraction algorithm progressively increased the centerline from the raw DEM until thresholds of elevation differences and slopes were reached. Based on the comparison with over 4000 differential global positioning system (GPS) measurements of the water surface collected in a 50 km reach of the Matane River, the longitudinal profile and slope estimates extracted from the raw and resampled LiDAR DEMs were in very good agreement with the field measurements (correlation coefficients ranging from 0 · 83 to 0 · 87) and can thus be used to compute stream power. The extracted width also corresponded very well to the channel as seen from ortho-photos, although the presence of bars in the Matane River increased the level of error in width estimates. The estimated maximum unit stream power spatial patterns corresponded well with field evidence of bank erosion, indicating that LiDAR DEMs can be used with confidence for initial hydro-geomorphological assessments. Copyright © 2013 John Wiley & Sons, Ltd.

Published

2013

8. Flood hazard mapping techniques with LiDAR in the absence of river bathymetry data

Author

Thomas Buffin-Bélanger, Guénolé Choné, and Pascale M. Biron

Subjects

lcsh:GE1-350, Hydrology, Accuracy and precision, 010504 meteorology & atmospheric sciences, Flood myth, 0208 environmental biotechnology, 02 engineering and technology, 01 natural sciences, Field (geography), 020801 environmental engineering, Lidar, Flood risk assessment, Calibration, Environmental science, Mapping techniques, Bathymetry, lcsh:Environmental sciences, 0105 earth and related environmental sciences

Abstract

In many areas of the world, flood risk assessment is either out of date or completely lacking. In Quebec (Canada), one of the challenges to map flood risk is the very large territory combined with very few datasets on river bathymetry, which are required to run hydraulic models. The objective of this study is to assess the precision and accuracy of 2D flood hydraulic modelling exclusively based on LiDAR elevation data which do not include information on in-channel river bathymetry. Hydraulic simulations (HEC-RAS 5.0) are carried out, for discharges of 20-, 100- and 500-year recurrence intervals, using two techniques that do not require bathymetry data, either subtracting discharge of the LiDAR survey from the flood discharge or estimating flow depth from the water surface slope. These techniques are compared to a traditional approach using bed topography obtained from detailed field surveys, on two long reaches (several kilometers). Sensitivity tests were conducted to assess the impacts of the main sources of error on simulated flood levels. Results show that both techniques can be applied with limited introduction of error in the modelled flood stages, and that errors are greatly reduced if calibration data are available.

Published

2018