Numerical Study of Run-up Oscillations over Fringing Reefs

Peláez-Zapata, D.S.; Montoya, R.D., and Osorio, A.F., 2018. Numerical study of run-up oscillations over fringing reefs. This work presents a numerical study of run-up oscillations over a typical fringing reef profile at the laboratory scale. The nonhydrostatic SWASH model was calibrated and validate...

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Bibliographic Details
Published inJournal of coastal research Vol. 34; no. 5; pp. 1065 - 1079
Main Authors Peláez-Zapata, D.S., Montoya, Rubén D., Osorio, Andrés F.
Format Journal Article
LanguageEnglish
Published Fort Lauderdale The Coastal Education and Research Foundation 01.09.2018
COASTAL EDUCATION & RESEARCH FOUNDATION, INC. [CERF]
Allen Press Inc
Subjects
Beaches
Bottom friction
Coastal engineering
Coasts
Coral reefs
Ecosystems
Energy
Energy levels
Engineering
Free surfaces
Fringing reefs
Gauges
High frequencies
High frequency
Levels
Mixing length
numerical modeling
Offshore
Offshore engineering
Oscillations
Parameter sensitivity
Parameterization
Parameters
Parametric equations
run-up spectrum
Sediment transport
Shoreline protection
Spectra
Spectral sensitivity
Surf zone
SWASH model
Swell
Wave run-up
Wave runup
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Summary:Peláez-Zapata, D.S.; Montoya, R.D., and Osorio, A.F., 2018. Numerical study of run-up oscillations over fringing reefs. This work presents a numerical study of run-up oscillations over a typical fringing reef profile at the laboratory scale. The nonhydrostatic SWASH model was calibrated and validated using experimental data of free surface elevation for eight gauges and run-up oscillations. The model shows a high sensitivity to variations in the parameters of bottom friction and horizontal mixing length. A process of calibration found the optimal values to be 0.014 s m−1/3 and 0.01 m, respectively. With these values, the model is good at reproducing bulk run-up parameters such as the mean run-up period (r2 = 0.93), sea-swell significant run-up (r2 = 0.93), and infragravity significant run-up (r2 = 0.88). The ratio between the infragravity and sea-swell run-up is highly dependent on the surf similarity parameter. For dissipative and intermediate conditions, the run-up is mainly dominated by low-frequency or infragravity oscillations, whereas for reflective conditions, high-frequency or sea-swell oscillations become more important. The results show that the run-up spectrum at high frequencies is proportional to f−4. The energy level at high frequencies is apparently independent of the offshore wave conditions and the width of the reef flat. However, the depth of the reef crest seems to be the most influential variable on the high-frequency energy. A parametric equation that depends on both the energy level at high frequency and a function of the run-up period was obtained to analyze the spectral characteristics of the wave run-up. This equation can be considered a first approach to a general parameterization of the run-up spectrum for reef zones, which can be useful in coastal engineering applications, such as predicting both the run-up height and frequency, spectral response of sediment transport in the swash zone, and coupling with spectral wave models.
ISSN:0749-0208
1551-5036
DOI:10.2112/JCOASTRES-D-17-00057.1