Does hydrological connectivity improve modelling of coarse sediment delivery in upland environments? |
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| Authors: | Simon C Reid Stuart N Lane David R Montgomery Christopher J Brookes |
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| Institution: | aSchool of Geography, University of Leeds, Leeds, LS2 9JT, UK;bDepartment of Geography, University of Durham, Durham, DH1 3LE, UK;cDepartment of Earth and Space Sciences/Quaternary Research Center, University of Washington, Seattle, WA98195, USA;dSchool of Earth Sciences, Victoria University of Wellington, PO Box 600, Wellington, New Zealand |
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| Abstract: | Modelling the delivery of landslide-generated sediment to channel networks is challenging due to uncertainty in the magnitude–frequency distribution of failures connected to the channel network. Here, we investigate a simplified treatment of hydrological connectivity as a means for improving identification of coarse sediment delivery to upland rivers. Sediment generation from hillslopes and channel banks and its delivery to the channel network are modelled based on a modified form of SHALSTAB coupled to a network index version of TOPMODEL. The network index treatment has two important hydrological effects: (a) it only allows saturated areas to connect to the hydrological network when there is full saturation along the associated flow path; and (2) overland flow associated with unconnected but saturated zones is assumed to remain within the catchment and to contribute to a reduction in the catchment-averaged saturation deficit. We use this hydrological treatment to restrict sediment delivery to situations where there is surface hydrological connection (i.e. saturation) along the complete flow path that connects failure areas to the drainage network. This represents an extreme restriction on the possibility of connected failure as it does not allow for failed material to connect if failures are associated with partial saturation or where delivery involves runout across areas where hydrological connection is not maintained. The impact of this restriction is assessed by comparing model predictions with field mapping of connected failures and data from continuously recording coarse sediment sensors, for two storm events. The hydrological connection requirement restricted connected failures to zones closer to the drainage network and resulted in a better level of agreement with the field mapped failures. Simulations suggested that in the study catchment the majority of sediment inputs occur from hydrologically-connected areas close to the channel network during moderate sized rainstorms that occur relatively frequently. |
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| Keywords: | TOPMODEL SHALSTAB SEDMAP Reduced complexity modelling Coarse sediment delivery Hydrological connectivity Network index Topographic index |
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