Climate change, sediment delivery and flood risk explored using two-dimensional inundation modelling
Détails
ID Serval
serval:BIB_FF86467AB574
Type
Actes de conférence (partie): contribution originale à la littérature scientifique, publiée à l'occasion de conférences scientifiques, dans un ouvrage de compte-rendu (proceedings), ou dans l'édition spéciale d'un journal reconnu (conference proceedings).
Collection
Publications
Institution
Titre
Climate change, sediment delivery and flood risk explored using two-dimensional inundation modelling
Titre de la conférence
River Flow 2006, Vols 1 and 2
ISBN
0-415-40815-6
Statut éditorial
Publié
Date de publication
2006
Editeur⸱rice scientifique
Ferreira RML, Alves CTL, Leal GAB, Cardoso AH
Série
Proceedings and Monographs in Engineering, Water and Earth Sciences
Pages
2147-2156
Notes
International Conference on Fluvial Hydraulics, Lisbon, PORTUGAL, SEP
06-08, 2006
06-08, 2006
Résumé
Much concern has been expressed about the potential impacts of changing
climate upon future flood risk. However, there has been much less
attention given to the ways in which changes in catchment function in
general, and sediment delivery in particular, might themselves impact
upon flood risk. This includes the effects of climate change upon
sediment delivery and hence upon changes in river channel conveyance
and hence flood risk. In this paper, we present the results of two
types of modeling. The first presents predictions of future sediment
delivery rates under future climate changes (estimated for the 2050s
and 2080s) in order to provide first order estimates of rates of
channel aggradation in an upland river with a gravelly bed. The second
couples measured channel geometry changes, over short timescales, to
flood events with 1 in 0.5 year and I in 2 year return periods, for
both the present, and for future climates (the 2050s and 2080s). This
coupling is achieved through a coupled 1D-2D model, with a full
solution of the 1D St.Venant equations for the channel and a 2D
diffusion wave treatment on the floodplain. Our results show that, for
the system and flood return periods studied, sedimentation rates are
the primary control upon the frequency of overbank flows and the
magnitude of flood inundation extent. However, these interact
non-linearly with future climate changes to increase future flood risk
dramatically. This leads us to make three important observations: (1)
we must consider what happens when historical flood events are modelled
contemporary geometrical surveys in aggrading systems, as this is
likely to yield unrealistically low friction parameters during the
parameterization process; (2) we must factor the indirect impacts of
future climate change upon sediment delivery into estimates of future
flood risk; and (3) we must think about how river management activities
impact upon the sedimentation process and make sure that the mechanisms
by which a channel maintains conveyance when subject to sediment
delivery are not undermined by river management activities.
climate upon future flood risk. However, there has been much less
attention given to the ways in which changes in catchment function in
general, and sediment delivery in particular, might themselves impact
upon flood risk. This includes the effects of climate change upon
sediment delivery and hence upon changes in river channel conveyance
and hence flood risk. In this paper, we present the results of two
types of modeling. The first presents predictions of future sediment
delivery rates under future climate changes (estimated for the 2050s
and 2080s) in order to provide first order estimates of rates of
channel aggradation in an upland river with a gravelly bed. The second
couples measured channel geometry changes, over short timescales, to
flood events with 1 in 0.5 year and I in 2 year return periods, for
both the present, and for future climates (the 2050s and 2080s). This
coupling is achieved through a coupled 1D-2D model, with a full
solution of the 1D St.Venant equations for the channel and a 2D
diffusion wave treatment on the floodplain. Our results show that, for
the system and flood return periods studied, sedimentation rates are
the primary control upon the frequency of overbank flows and the
magnitude of flood inundation extent. However, these interact
non-linearly with future climate changes to increase future flood risk
dramatically. This leads us to make three important observations: (1)
we must consider what happens when historical flood events are modelled
contemporary geometrical surveys in aggrading systems, as this is
likely to yield unrealistically low friction parameters during the
parameterization process; (2) we must factor the indirect impacts of
future climate change upon sediment delivery into estimates of future
flood risk; and (3) we must think about how river management activities
impact upon the sedimentation process and make sure that the mechanisms
by which a channel maintains conveyance when subject to sediment
delivery are not undermined by river management activities.
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Création de la notice
03/02/2011 15:40
Dernière modification de la notice
20/08/2019 17:29
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