Wind Wave Modelling Over the Baltic Sea Using Wam Model and the Coupled Ocean Circulation-Wave Pom Model

Cieślikiewicz, Witold; Dudkowska, A; Janowczyk, Roman; Roščinski, Vitalij; Roziewski, Szymon; Badur, Jordan

doi:10.9753/icce.v34.posters.42

Cited by 3 publications

(4 citation statements)

References 3 publications

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“…The wind-generated wave field was computed using the model WAM cycle 4 (WAMDI Group 1988) implemented within the framework of the project PROZA project (Cieślikiewicz et al 2014) in the Baltic Sea with the SWAN series III (Booij et al 1999) being applied to the Gulf of Gdańsk. The models were operating in nested grids: 5 Nm in the Baltic Sea (WAM), 200 m in the Gulf of Gdańsk (SWAN), and 50 m in the Puck Bay (SWAN).…”

Section: Hydrodynamic Conditionsmentioning

confidence: 99%

Assessment of the potential for dredged material dispersal from dumping sites in the Gulf of Gdańsk

et al. 2018

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Purpose Environment-friendly management of sites used for disposal of locally generated sedimentary material involves designation of an optimal dumping site location which will render the dredged material re-usable for beneficial purposes. The objective of this research was to determine whether wind, waves, and currents can induce transport of sediment from offshore dumping sites located at intermediate depths in the southern Baltic. Materials and methods The problem was addressed by exploring potential sediment transport from two sites located in the Gulf of Gdańsk at depths of about 20 m. A total of 29 combinations of hydrodynamic variables, representing the most extreme possible situations in the area, including eight theoretical uniform wind fields over the entire Baltic Sea from the W, NW, N, NE, E, SE, S, and SW sectors, the wind speed of 30 m s −1 , as well as 21 historical extreme storms, retrieved from the HIPOCAS project database, were used. Results and discussion The bottom velocities resulting from waves and currents at the dumping sites considered were computed using wave models (WAM, SWAN) and the M3D hydrodynamic model (based on the POM model). To estimate the velocities critical for bedload transport, formulae developed by Soulsby (1997) and Sawamoto and Yamashita (Proc Coastal Sediments 87:415-423, 1987) were used. The volumetric bedload transport was computed based on Meyer-Peter and Müller (1948). The model simulations demonstrated that, for the storm conditions analyzed, the current velocity in the area of the two dumping sites would be so low that it would practically not affect the magnitude of the bottom sediment transport. Thus, the resultant volume of bedload transported would be equal to that generated by the wave action. For the heaviest historical storm, the maximum transport is about 3 × 10 −5 m 2 s −1. Conclusions Under conditions of theoretical storms, the bottom orbital velocities would be higher and the resultant sediment transport would reach almost 7 × 10 −5 m 2 s −1 for northerly winds. However, this value is still very low compared with the volume of sediment being dumped. The findings of this study may prove useful in designation of future dumping sites.

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Section: Hydrodynamic Conditionsmentioning

confidence: 99%

Assessment of the potential for dredged material dispersal from dumping sites in the Gulf of Gdańsk

et al. 2018

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“…Additionally, the WAM model, which provides the boundary conditions for SWAN, also tends to underestimate values of H S and T . Modelling results of WAM, with the model configuration as used in this research, were validated against buoy measurements within the frame of the PROZA project (Cieślikiewicz et al 2014); estimated underestimations were of about 2% for H S and 9% for T. Regarding the M3D model, in view of hitherto lack of current measurements, the model was submitted to comprehensive validation against long-term observations of sea level, salinity, temperature and satellite images of SST. Quite satisfactory correlation coefficients were obtained (Jędrasik 2005).…”

Section: Uncertainties In Modellingmentioning

confidence: 99%

“…While hindcasting with SWAN the 21 selected historical storms, the boundary condition data were extracted from the HIPOCAS wave parameter database. For modelling of the eight created artificial uniform storms, the WAM model implementation and setup developed in IOUG within the PROZA project (Cieślikiewicz et al 2014) has been applied.…”

Section: Wind Waves-the Gulf and Coastal Zonementioning

confidence: 99%

Extreme bottom velocities induced by wind wave and currents in the Gulf of Gdańsk

et al. 2017

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The principal goal of this study is to get some preliminary insights about the intensity of water movement generated by wind waves, and due to the currents in the bottom waters of Gulf of Gdańsk, during severe storms. The Gulf of Gdańsk is located in the southern Baltic Sea. This paper presents the results of analysis of wave and current-induced velocities during extreme wind conditions, which are determined based on long-term historical records. The bottom velocity fields originated from wind wave and wind currents, during analysed extreme wind events, are computed independently of each other. The long-term wind wave parameters for the Baltic Sea region are derived from the 44-year hindcast wave database generated in the framework of the project HIPOCAS funded by the European Union. The output from the numerical wave model WAM provides the boundary conditions for the model SWAN operating in high-resolution grid covering the area of the Gulf of Gdańsk. Wind current velocities are calculated with the M3D hydrodynamic model developed in the Institute of Oceanography of the University of Gdańsk based on the POM model. The three dimensional current fields together with trajectories of particle tracers spreading out of bottom boundary layer are modelled, and the calculated fields of bottom velocities are presented in the form of 2D maps. During northerly winds, causing in the Gulf of Gdańsk extreme waves and most significant wind-driven circulation, the wave-induced bottom velocities are greater than velocities due to currents. The current velocities in the bottom layer appeared to be smaller by an order of magnitude than the wave-induced bottom orbital velocities. Namely, during most severe northerly storms analysed, current bottom velocities ranged about 0.1-0.15 m/s, while the root mean square of wave-induced near-seabed velocities reached maximum values of up to 1.4 m/s in the southern part of Gulf of Gdańsk.

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“…The WAM wave prediction model has become a standard tool for operational wave prediction as well as for research and engineering applications. In the present paper, the WAM Cycle 4.5 was used (Günther & Behrens, 2012) with horizontal resolution of five nautical miles (see also Cieślikiewicz et al, 2014).…”

Section: Wave Field Modellingmentioning

confidence: 99%

Wave-induced bedload transport – a study of the southern Baltic coastal zone

Dudkowska

Gic-Grusza

2017

Geologos

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The wave-induced bedload transport and spatial distribution of its magnitude in the southern Baltic coastal zone of Poland are estimated. The vicinity of Lubiatowo was selected as a representative part of the Polish coast. It was assumed that transport is a function of shear stress; alternative approaches, based on force balances and discharge relationships, were not considered in the present study. Four models were studied and compared over a wide range of bottom shear stress and wind-wave conditions. The set of models comprises classic theories that assume a simplified influence of turbulence on sediment transport (e.g., advocated by authors such as Du Boys, Meyer-Peter and Müller, Ribberink, Engelund and Hansen). It is shown that these models allow to estimate transport comparable to measured values under similar environmental conditions. A united general model for bedload transport is proposed, and a set of maps of wave bedload transport for various wind conditions in the study area is presented.

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Wind Wave Modelling Over the Baltic Sea Using Wam Model and the Coupled Ocean Circulation-Wave Pom Model

Cited by 3 publications

References 3 publications

Assessment of the potential for dredged material dispersal from dumping sites in the Gulf of Gdańsk

Assessment of the potential for dredged material dispersal from dumping sites in the Gulf of Gdańsk

Extreme bottom velocities induced by wind wave and currents in the Gulf of Gdańsk

Wave-induced bedload transport – a study of the southern Baltic coastal zone

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