Prediction modeling of coastal sediment transport using accelerated smooth particle hydrodynamics approach.

A GPU-accelerated 3D smooth particle hydrodynamics (SPH) scheme is developed and applied to a coastal multi-phase liquid-sediment interaction and sediment transport. The SPH scheme's meshless design and the sediment's particle structure enable the modeling of the waves' interactions with the sediment particles beyond the limitation of the mesh-based methods. A Newtonian constitutive model is used to model the liquid phase, and the sediment transport is formulated based on the Herschel-Bulkley-Papanastasiou (HBP) model. The yield characteristics of the sediment phase are estimated using the Drucker-Prager yield criterion. Due to the parallelization of the solution on graphics processing units, the 3D SPH scheme's performance, which uses millions of particles, is improved. Good correlations were observed in the SPH predictions and experimental measurements, with a maximum difference of 4.85 %. The validated scheme is applied to formulate forecasting models for the coastline sediment transport. It is found that erosion and scouring are expected at the coastline region inclined to the direction of the sea waves, with a predicted mass erosion of about 60e3 kg in four years. The wave's velocity is also established to be directly proportional to the sediment transport. The proposed multi-phase SPH methodology is proven effective for sediment transport prediction. • PIV and 3D SPH approaches are developed to study the morphodynamics variables of a coastal liquid-sediment system. • The approaches are applied to analyze the multi-phase liquid-sediment interaction phenomenon of the coastline. • The findings of the presented SPH model show good correlation with those of the PIV experiment. • The ability of the presented method to investigate the coastline sediment transport is demonstrated. • Forecast models are formulated for predicting the coastline sediment transport as a function of time and wave velocity. [ABSTRACT FROM AUTHOR]