Modelling the effects of normal faulting on alluvial river meandering

Hessel A G Woolderink; Steven A H Weisscher; Maarten G Kleinhans; Cornelis Kasse; Ronald T van Balen

doi:10.1002/esp.5315

Modelling the effects of normal faulting on alluvial river meandering

Earth Surf Process Landf. 2022 Apr;47(5):1252-1270. doi: 10.1002/esp.5315. Epub 2022 Feb 5.

Authors

Hessel A G Woolderink¹, Steven A H Weisscher², Maarten G Kleinhans², Cornelis Kasse¹, Ronald T van Balen^{1

3}

Affiliations

¹ Faculty of Science, Earth and Climate Cluster Vrije Universiteit Amsterdam Amsterdam HV the Netherlands.
² Department of Physical Geography, Faculty of Geosciences Utrecht University Utrecht TC the Netherlands.
³ TNO Geological Survey of the Netherlands Utrecht TA the Netherlands.

Abstract

The meandering of alluvial rivers may be forced by normal faulting due to tectonically altered topographic gradients of the river valley and channel at and near the fault zone. Normal faulting can affect river meandering by either instantaneous (e.g. surface-rupturing earthquakes) or gradual displacement. To enhance our understanding of river channel response to tectonic faulting at the fault zone scale we used the physics-based, two-dimensional morphodynamic model Nays2D to simulate the responses of a laboratory-scale alluvial river with vegetated floodplain to various faulting and offset scenarios. The results of a model with normal fault downstepping in the downstream direction show that channel sinuosity and bend radius increase up to a maximum as a result of the faulting-enhanced valley gradient. Hereafter, a chute cutoff reduces channel sinuosity to a new dynamic equilibrium value that is generally higher than the pre-faulting sinuosity. A scenario where a normal fault downsteps in the upstream direction leads to reduced morphological change upstream of the fault due to a backwater effect induced by the faulting. The position within a meander bend at which faulting occurs has a profound influence on the evolution of sinuosity; fault locations that enhance flow velocities over the point bar during floods result in a faster sinuosity increase and subsequent chute cutoff than locations that enhance flow velocity directed towards the floodplain. This upward causation from the bend scale to the reach and floodplain scale arises from the complex interactions between meandering and floodplain and the nonlinearities of the sediment transport and chute cutoff processes. Our model results provide a guideline to include process-based reasoning in the interpretation of geomorphological and sedimentological observations of fluvial response to faulting. The combination of these approaches leads to better predictions of possible effects of faulting on alluvial river meandering.

Keywords: alluvial rivers; faulting; meandering; modelling; morphodynamics; morphology; neotectonic; tectonic.