Towards resolving bedload flux variability

Bedload transport occurs when a bed composed of sedimentary grains becomes mobile in response to the shearing by a flow of liquid. It shapes the landscapes of Earth and other planetary bodies by promoting the formation and growth of various multiscale geological features. Estimating the rate at which such processes take place requires accurate bedload flux predictions. However, even for highly idealized conditions in the laboratory, study-to-study variability of reported bedload flux measurements borders an order of magnitude. This uncertainty stems from physically poorly supported, typically empirical methods of determining the transport-driving bed shear stress, especially for very narrow or shallow channel flows, and from study-to-study grain shape variations. Here, we derive a non-empirical method of bed shear stress determination and apply it to a number of independent grain-shape-controlled data sets, based on well-controlled experiments and CFD-DEM simulations, for a very diverse range of transport conditions. An existing physical bedload model, here generalized to account for grain shape variability, predicts almost all these data within a factor of 1.3, whereas a prominent alternative model (Deal et al., Nature 613, 298-302, 2023) seems falsified.