FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W3205312974> ?p ?o ?g. }

• W3205312974 abstract "Coastal communities across the globe are often protected by structures, such as seawalls, levees or dikes, which allow only a safe volume of water to pass over or “overtop” them due to wave action during storms. The area seaward of these structures is often characterised by shallow, gently sloping beds referred to as foreshores. As storm waves propagate over the shallow foreshores, two notable processes occur. The first, is the attenuation of high-frequency waves that are collectively referred to as wind-sea and swell (SS), with periods less than 20 seconds. The limited water depth over the foreshore forces the SS waves to shoal and ultimately break. This shoaling and breaking, in turn, results in the second important process: the growth of infragravity (IG) waves, with periods in the order of minutes. The methods used in current practice to estimate wave overtopping are able to accurately quantify the impact of SS waves. However, they tend to neglect the influence of IG waves, which are known to play a critical role in erosion and flooding along shallow coast lines. In light of this, this dissertation aimed to develop new methods to estimate the influence of IG waves on the safety of coastal defences with shallow foreshores against wave overtopping. This aim was ultimately achieved by using state-of-art numerical models, empirical methods and field measurements to develop a suite of tools, that together, provide a framework to accurately quantify the influence of IG waves on wave overtopping. As data on shallow foreshores was limited, a numerical model (XBeach Non-hydrostatic) was first used to generate a large dataset of wave measurements at the toe of the structure for varying offshore, foreshore and structure slope conditions. The analysis, detailed in Chapter 2, revealed that the influence of IG waves increased for higher, directionally narrow-banded (long-crested) offshore waves; shallower foreshore water depths; milder foreshore slopes; and reduced vegetated cover. The combined effect of the different environmental parameters on the IG waves was then captured in an empirical model, which formed the base of the framework to follow. For determining wave overtopping, the standard approach requires the use of a wave model (often a phase-averaged model like SWAN) to estimate wave parameters at the toe, which are then used as input to the well-known formulae of the EurOtop design manual. However, this approach largely neglects the impact of IG waves. In Chapter 3, this is rectified by augmenting the traditional approach with the empirical model developed in Chapter 2 to include the effects of the IG waves on the design parameters. Considering accuracy and computational demand, the modified approach proved superior when assessing wave overtopping at dikes with shallow foreshores. This approach formed the first sub-method to estimating wave overtopping in the overall framework. Nevertheless, it is often difficult to obtain accurate estimates of wave parameters at the toe of structures with shallow foreshores. Chapter 4 offers a solution to this problem by proposing a new set of overtopping formulae that instead rely on deep-water wave parameters as input. This is done by revisiting the old but proven approach of Yoshimi Goda, now with additional data and new trend analysis techniques. The newly-derived formulae proved accurate and can be considered an alternative to the current standard (Chapter 3). Particularly, for dikes and seawalls with very and extremely shallow foreshores, where IG waves tend to dominate. This approach formed the second sub-method to estimating wave overtopping in the overall framework. Finally, in order to estimate the impact of IG waves on safety, a probabilistic method (FORM) was introduced to the framework in Chapter 5. Using the first sub-method (Chapter 3), the probability of dike failure by wave overtopping with and without IG waves was determined for dikes along the shallow Dutch Wadden Sea coast. Including the IG waves resulted in 1.1 to 1.6 times higher failure probabilities for the Dutch Wadden Sea coast, suggesting that coastal safety may be overestimated when they are neglected. This was attributed to the influence of the IG waves on the wave period and, to a lesser extent, the wave height at the structure toe. Furthermore, the spatial variation in this effect observed for the Dutch Wadden Sea highlighted its dependence on local bathymetric and offshore forcing conditions—with IG waves having greater influence on the failure probability for cases with larger offshore waves and shallower water depths. The general conclusion of the dissertation is that IG waves can have an important impact on safety. Moreover, findings indicate that the safety of existing coastal defences with shallow foreshores may be overestimated, since IG waves are largely neglected in the current practice for their design and assessment. For the case considered here (the Dutch Wadden Sea), the increase in required crest level due to the IG waves was around 2 dm with a cost in the order of M€1/per km. For shallower coastlines exposed to more energetic wave conditions, the influence of the IG waves and the corresponding safety costs are likely to be greater. This dissertation provides practitioners with a suite of tools to quantify to influence of IG waves on the safety of coastal defences with shallow foreshores against wave overtopping. Thereby, reducing the uncertainty in the overall impact of shallow foreshores and allowing dike managers to make more informed decisions when considering hazard mitigation strategies." @default.
• W3205312974 created "2021-10-25" @default.
• W3205312974 creator A5030054380 @default.
• W3205312974 date "2021-10-18" @default.
• W3205312974 modified "2023-09-23" @default.
• W3205312974 title "The Influence of Infragravity Waves on Overtopping at Coastal Structures with Shallow Foreshores" @default.
• W3205312974 doi "https://doi.org/10.4233/uuid:f93143bc-0214-41ad-af4a-4ad2168a42a5" @default.
• W3205312974 hasPublicationYear "2021" @default.
• W3205312974 type Work @default.
• W3205312974 sameAs 3205312974 @default.
• W3205312974 citedByCount "0" @default.
• W3205312974 crossrefType "journal-article" @default.
• W3205312974 hasAuthorship W3205312974A5030054380 @default.
• W3205312974 hasConcept C105306849 @default.
• W3205312974 hasConcept C108628306 @default.
• W3205312974 hasConcept C111368507 @default.
• W3205312974 hasConcept C114793014 @default.
• W3205312974 hasConcept C11693305 @default.
• W3205312974 hasConcept C121332964 @default.
• W3205312974 hasConcept C127313418 @default.
• W3205312974 hasConcept C132651083 @default.
• W3205312974 hasConcept C143351421 @default.
• W3205312974 hasConcept C16156107 @default.
• W3205312974 hasConcept C165082838 @default.
• W3205312974 hasConcept C165205528 @default.
• W3205312974 hasConcept C169596890 @default.
• W3205312974 hasConcept C17409809 @default.
• W3205312974 hasConcept C174580923 @default.
• W3205312974 hasConcept C186348155 @default.
• W3205312974 hasConcept C190791664 @default.
• W3205312974 hasConcept C2777774347 @default.
• W3205312974 hasConcept C2816523 @default.
• W3205312974 hasConcept C43179477 @default.
• W3205312974 hasConcept C44886760 @default.
• W3205312974 hasConcept C62520636 @default.
• W3205312974 hasConcept C65589250 @default.
• W3205312974 hasConcept C7266685 @default.
• W3205312974 hasConcept C83877588 @default.
• W3205312974 hasConcept C83893233 @default.
• W3205312974 hasConceptScore W3205312974C105306849 @default.
• W3205312974 hasConceptScore W3205312974C108628306 @default.
• W3205312974 hasConceptScore W3205312974C111368507 @default.
• W3205312974 hasConceptScore W3205312974C114793014 @default.
• W3205312974 hasConceptScore W3205312974C11693305 @default.
• W3205312974 hasConceptScore W3205312974C121332964 @default.
• W3205312974 hasConceptScore W3205312974C127313418 @default.
• W3205312974 hasConceptScore W3205312974C132651083 @default.
• W3205312974 hasConceptScore W3205312974C143351421 @default.
• W3205312974 hasConceptScore W3205312974C16156107 @default.
• W3205312974 hasConceptScore W3205312974C165082838 @default.
• W3205312974 hasConceptScore W3205312974C165205528 @default.
• W3205312974 hasConceptScore W3205312974C169596890 @default.
• W3205312974 hasConceptScore W3205312974C17409809 @default.
• W3205312974 hasConceptScore W3205312974C174580923 @default.
• W3205312974 hasConceptScore W3205312974C186348155 @default.
• W3205312974 hasConceptScore W3205312974C190791664 @default.
• W3205312974 hasConceptScore W3205312974C2777774347 @default.
• W3205312974 hasConceptScore W3205312974C2816523 @default.
• W3205312974 hasConceptScore W3205312974C43179477 @default.
• W3205312974 hasConceptScore W3205312974C44886760 @default.
• W3205312974 hasConceptScore W3205312974C62520636 @default.
• W3205312974 hasConceptScore W3205312974C65589250 @default.
• W3205312974 hasConceptScore W3205312974C7266685 @default.
• W3205312974 hasConceptScore W3205312974C83877588 @default.
• W3205312974 hasConceptScore W3205312974C83893233 @default.
• W3205312974 hasLocation W32053129741 @default.
• W3205312974 hasOpenAccess W3205312974 @default.
• W3205312974 hasPrimaryLocation W32053129741 @default.
• W3205312974 hasRelatedWork W121090479 @default.
• W3205312974 hasRelatedWork W2041156061 @default.
• W3205312974 hasRelatedWork W2095062146 @default.
• W3205312974 hasRelatedWork W2128897734 @default.
• W3205312974 hasRelatedWork W2319822995 @default.
• W3205312974 hasRelatedWork W2333133335 @default.
• W3205312974 hasRelatedWork W2370638797 @default.
• W3205312974 hasRelatedWork W2425617688 @default.
• W3205312974 hasRelatedWork W2884838714 @default.
• W3205312974 hasRelatedWork W2906033965 @default.
• W3205312974 hasRelatedWork W3003227764 @default.
• W3205312974 hasRelatedWork W3015394192 @default.
• W3205312974 hasRelatedWork W3032568577 @default.
• W3205312974 hasRelatedWork W3034445177 @default.
• W3205312974 hasRelatedWork W3035756493 @default.
• W3205312974 hasRelatedWork W3116351371 @default.
• W3205312974 hasRelatedWork W3183978494 @default.
• W3205312974 hasRelatedWork W3197490826 @default.
• W3205312974 hasRelatedWork W330106056 @default.
• W3205312974 hasRelatedWork W640434569 @default.
• W3205312974 isParatext "false" @default.
• W3205312974 isRetracted "false" @default.
• W3205312974 magId "3205312974" @default.
• W3205312974 workType "article" @default.