Abstract
The performance of a recently developed “stabilized” turbulence ()
closure model, which avoids un-physical over-production of turbulence
prior to wave breaking, is investigated in the computational fluid
dynamics (CFD) simulation of cross-shore sediment transport and breaker
bar morphology. Comparisons are made with experiments as well as results
from simulations employing (otherwise identical) “standard” turbulence
closure. The stabilized turbulence model is demonstrated to result in
major (qualitative and quantitative) improvements of the predicted
breaker bar position and height. Conversely, the established
over-production of turbulence in the standard closure, coupled with
associated inaccurate undertow structure in the outer surf zone,
contribute to erroneous offshore migration of the breaker bar. By
correcting these shortcomings, the stabilized turbulence closure model
rightly predicts initial onshore morphological migration of the breaker
bar without any calibration. This work thus establishes proper
turbulence modeling as a prerequisite for accurate CFD prediction of
cross-shore sediment transport and profile morphology.
Original language | English |
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Article number | 104269 |
Journal | Coastal Engineering |
Volume | 180 |
Number of pages | 8 |
ISSN | 0378-3839 |
DOIs | |
Publication status | Published - 2023 |
Keywords
- Breaker bar development
- Breaking waves
- CFD
- Morphology
- Sediment transport
- Turbulence modeling