Litcius/Paper detail

Quantifying hydraulic roughness in a riparian forest using a drag force‐based method

Richard Sharpe, Andrew Brooks, Jon Olley, Justine Kemp

2023Journal of Flood Risk Management11 citationsDOIOpen Access PDF

Abstract

Abstract Flow resistance through riparian forests due to drag on trees is often expressed in hydraulic models with an increase in a boundary resistance factor such as Manning's n . However, when Manning's n is used as a proxy for vegetation drag, this parameter is dependent on flow conditions and a single, uniform value may be inadequate for simulating a broad range of flood magnitudes. To investigate this issue, flow resistance, and the commensurate Manning's n values through a riparian forest were computed using measured drag forces and estimates of the forest structure and tree morphology. The computed Manning's n values were applied to a 2D hydraulic model (TUFLOW) to simulate an observed flood and a range of design floods. Modelled peak flood levels for the observed flood were 0.16 m lower on average than that recorded at debris marks. There was little difference in modelled flood levels when using the computed Manning's n compared to a traditional, uniform Manning's n . Reassuringly, the traditional method appears adequate when reliable calibration data is available. Otherwise, the method developed here provides a useful alternative in cases where calibration data is limited or for testing reforestation as a nature‐based solution in river or flood management.

Topics & Concepts

Riparian zoneDragFlood mythHydrology (agriculture)Hydraulic roughnessEnvironmental scienceStreamflowRange (aeronautics)GeologyGeotechnical engineeringSurface finishGeographyEcologyPhysicsEngineeringMechanicsBiologyCartographyAerospace engineeringHabitatMechanical engineeringDrainage basinArchaeologyHydrology and Sediment Transport ProcessesSoil erosion and sediment transportHydrology and Watershed Management Studies