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Due to the ongoing rise in sea level and increases in extreme wave climates, which consequently change the wave climate, coastal structures such as sea dikes and seawalls are exposed to severe and frequent sea storms. Even though much research related to wave–structure interactions has been carried out, it remains one of the most important and challenging topics in the field of coastal engineering. The recent publications in the Special Issue “Wave Interactions with Coastal Structures” in the Journal of Marine Science and Engineering include a wide range of research, including theoretical/mathematical, experimental, and numerical work related to the interaction between sea waves and coastal structures. These publications address conventional coastal hard structures in deep water zones as well as those located in shallow water zones, such as wave overtopping over shallow foreshores with apartment buildings on dikes. The research findings presented help to improve our knowledge of hydrodynamic processes, and the new approaches and developments presented here will be good benchmarks for future work.

Technology: general issues --- History of engineering & technology --- shallow waters --- wave energy --- coastal erosion --- beach restoration --- submerged breakwaters --- protected nourishments --- wave overtopping --- coastal safety --- flow velocity --- flow depth --- sea dikes --- overtopping reduction --- force reduction --- oblique waves --- storm return wall --- EurOtop manual --- validation --- wave modelling --- shallow foreshore --- dike-mounted vertical wall --- wave impact loads --- OpenFOAM --- average overtopping discharge --- individual volume --- overtopping flow depth --- overtopping flow velocity --- promenade --- vertical wall --- SWASH --- fluid-structure interaction --- waves --- smoothed particle hydrodynamics --- SPH --- Pont del Petroli --- storm Gloria --- inter-model comparison --- DualSPHysics --- wave pressure --- caisson breakwater --- stability --- RANS model --- solitary wave --- fully nonlinear wave --- three-dimensional wave --- partially submerged cylinder --- hollow circular cylinder --- tsunami --- wave --- bore --- flooding --- debris --- numerical modeling --- SPH-FEM coupling --- coastal structures --- shallow waters --- wave energy --- coastal erosion --- beach restoration --- submerged breakwaters --- protected nourishments --- wave overtopping --- coastal safety --- flow velocity --- flow depth --- sea dikes --- overtopping reduction --- force reduction --- oblique waves --- storm return wall --- EurOtop manual --- validation --- wave modelling --- shallow foreshore --- dike-mounted vertical wall --- wave impact loads --- OpenFOAM --- average overtopping discharge --- individual volume --- overtopping flow depth --- overtopping flow velocity --- promenade --- vertical wall --- SWASH --- fluid-structure interaction --- waves --- smoothed particle hydrodynamics --- SPH --- Pont del Petroli --- storm Gloria --- inter-model comparison --- DualSPHysics --- wave pressure --- caisson breakwater --- stability --- RANS model --- solitary wave --- fully nonlinear wave --- three-dimensional wave --- partially submerged cylinder --- hollow circular cylinder --- tsunami --- wave --- bore --- flooding --- debris --- numerical modeling --- SPH-FEM coupling --- coastal structures

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Due to the ongoing rise in sea level and increases in extreme wave climates, which consequently change the wave climate, coastal structures such as sea dikes and seawalls are exposed to severe and frequent sea storms. Even though much research related to wave–structure interactions has been carried out, it remains one of the most important and challenging topics in the field of coastal engineering. The recent publications in the Special Issue “Wave Interactions with Coastal Structures” in the Journal of Marine Science and Engineering include a wide range of research, including theoretical/mathematical, experimental, and numerical work related to the interaction between sea waves and coastal structures. These publications address conventional coastal hard structures in deep water zones as well as those located in shallow water zones, such as wave overtopping over shallow foreshores with apartment buildings on dikes. The research findings presented help to improve our knowledge of hydrodynamic processes, and the new approaches and developments presented here will be good benchmarks for future work.

shallow waters --- wave energy --- coastal erosion --- beach restoration --- submerged breakwaters --- protected nourishments --- wave overtopping --- coastal safety --- flow velocity --- flow depth --- sea dikes --- overtopping reduction --- force reduction --- oblique waves --- storm return wall --- EurOtop manual --- validation --- wave modelling --- shallow foreshore --- dike-mounted vertical wall --- wave impact loads --- OpenFOAM --- average overtopping discharge --- individual volume --- overtopping flow depth --- overtopping flow velocity --- promenade --- vertical wall --- SWASH --- fluid–structure interaction --- waves --- smoothed particle hydrodynamics --- SPH --- Pont del Petroli --- storm Gloria --- inter-model comparison --- DualSPHysics --- wave pressure --- caisson breakwater --- stability --- RANS model --- solitary wave --- fully nonlinear wave --- three-dimensional wave --- partially submerged cylinder --- hollow circular cylinder --- tsunami --- wave --- bore --- flooding --- debris --- numerical modeling --- SPH–FEM coupling --- coastal structures --- n/a --- fluid-structure interaction --- SPH-FEM coupling

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This Special Issue publishes the latest advances and developments concerning the modelling of flooding in urban areas and contributes to our scientific understanding of the flooding processes and the appropriate evaluation of flood impacts. This issue contains contributions of novel methodologies including flood forecasting methods, data acquisition techniques, experimental research in urban drainage systems and/or sustainable drainage systems, and new numerical and simulation approaches in nine papers with contributions from over forty authors.

machine learning --- flash flood --- GIS --- Iran --- decision trees --- ensemble techniques --- manhole flooding --- urban flooding --- grid-based modeling --- SWWM --- FIRM --- pollutant transport --- hydraulic structures --- urban drainage --- CFD --- dual drainage --- Iber --- SWMM --- hazard --- artificial neural network --- resilient backpropagation --- multistep urban flood forecast --- demographic change --- urbanization --- flooding --- drainage system --- vulnerability --- Sub-Saharan Africa --- Antananarivo --- parameterised power-linear model --- hyper concentration --- dilute concentration --- suspended sediment transport --- flood --- sediment size parameter --- rouse number --- mean concentration --- flow depth --- urban flood modeling --- porosity --- shallow-water model --- urban flood management --- flood forecasting --- weather radar --- integrated hydraulic modeling --- and evacuation lead time --- n/a

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This book is the result of a stimulating Special Issue of Water, focusing on the “Interaction between waves and Maritime Structures”. This broadly inclusive title allowed the gathering of articles on different topics of engineering concern, making the book appeal to both scientists and practical engineers. Original contributions on evergreen problems, such as wave overtopping at conventional and unconventional coastal structures, wave-induced pressures at vertical walls, hydraulic stability of rubble mound breakwaters and dynamics of crown-walls indeed represent the main core of the book; however, other intriguing research topics are also tackled, including the solution of the Navier–Stokes equations for biphase flows, the downscaling of large maritime structures in a physical lab, floating bodies mechanics and the numerical modeling of coastline evolution.

Technology: general issues --- rock armor stability --- breakwater --- damage --- notional permeability factor --- crown wall failure --- dynamic response --- sliding --- overturning --- bearing capacity --- ship motions --- in-situ observations --- port operation --- transfer functions --- meteorological and ocean conditions --- vessel dimensions --- electrical platform --- hydrodynamic response --- strain --- acceleration --- hydroelastic similarity --- laboratory experiment --- wave overtopping --- flow velocity --- flow depth --- dike --- wave breaking --- experiments --- numerical modelling --- n/a --- floating cylinder --- water filled --- motion capturing --- wave tank --- wave gauges --- fluid–structure interaction --- free surface --- sloshing --- image analysis --- green water --- wet dam-break bore --- 2D experimental study --- water elevation database --- Venetian lagoon --- flooding --- astronomical tide --- storm surge --- experimental investigation --- two-phase flows --- fluid-structure interactions --- wave decomposition --- floating body --- recurves --- recurve geometry --- vertical seawalls --- wave loads and pressures --- pulsating and impulsive conditions --- validation experiment --- shoreline evolution --- littoral drift --- equivalent wave --- one-line equation --- coastal defenses --- structure response --- fluid-structure interaction

Choose an application

• Reference Manager
• EndNote
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This book is the result of a stimulating Special Issue of Water, focusing on the “Interaction between waves and Maritime Structures”. This broadly inclusive title allowed the gathering of articles on different topics of engineering concern, making the book appeal to both scientists and practical engineers. Original contributions on evergreen problems, such as wave overtopping at conventional and unconventional coastal structures, wave-induced pressures at vertical walls, hydraulic stability of rubble mound breakwaters and dynamics of crown-walls indeed represent the main core of the book; however, other intriguing research topics are also tackled, including the solution of the Navier–Stokes equations for biphase flows, the downscaling of large maritime structures in a physical lab, floating bodies mechanics and the numerical modeling of coastline evolution.

Technology: general issues --- rock armor stability --- breakwater --- damage --- notional permeability factor --- crown wall failure --- dynamic response --- sliding --- overturning --- bearing capacity --- ship motions --- in-situ observations --- port operation --- transfer functions --- meteorological and ocean conditions --- vessel dimensions --- electrical platform --- hydrodynamic response --- strain --- acceleration --- hydroelastic similarity --- laboratory experiment --- wave overtopping --- flow velocity --- flow depth --- dike --- wave breaking --- experiments --- numerical modelling --- floating cylinder --- water filled --- motion capturing --- wave tank --- wave gauges --- fluid-structure interaction --- free surface --- sloshing --- image analysis --- green water --- wet dam-break bore --- 2D experimental study --- water elevation database --- Venetian lagoon --- flooding --- astronomical tide --- storm surge --- experimental investigation --- two-phase flows --- fluid-structure interactions --- wave decomposition --- floating body --- recurves --- recurve geometry --- vertical seawalls --- wave loads and pressures --- pulsating and impulsive conditions --- validation experiment --- shoreline evolution --- littoral drift --- equivalent wave --- one-line equation --- coastal defenses --- structure response --- rock armor stability --- breakwater --- damage --- notional permeability factor --- crown wall failure --- dynamic response --- sliding --- overturning --- bearing capacity --- ship motions --- in-situ observations --- port operation --- transfer functions --- meteorological and ocean conditions --- vessel dimensions --- electrical platform --- hydrodynamic response --- strain --- acceleration --- hydroelastic similarity --- laboratory experiment --- wave overtopping --- flow velocity --- flow depth --- dike --- wave breaking --- experiments --- numerical modelling --- floating cylinder --- water filled --- motion capturing --- wave tank --- wave gauges --- fluid-structure interaction --- free surface --- sloshing --- image analysis --- green water --- wet dam-break bore --- 2D experimental study --- water elevation database --- Venetian lagoon --- flooding --- astronomical tide --- storm surge --- experimental investigation --- two-phase flows --- fluid-structure interactions --- wave decomposition --- floating body --- recurves --- recurve geometry --- vertical seawalls --- wave loads and pressures --- pulsating and impulsive conditions --- validation experiment --- shoreline evolution --- littoral drift --- equivalent wave --- one-line equation --- coastal defenses --- structure response