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The impact of climate change effects on the planform of a headland-bay beach on the southern coast of South AfricaHugo, Pierre-Malan 03 1900 (has links)
Thesis (MScEng)--Stellenbosch University, 2013. / ENGLISH ABSTRACT: The various consequences of climate change pose a significant threat to developments near the
coast. These threats include saltwater intrusion, coastal erosion and flooding. In the coastal context,
the climate change effect often raising the most concern is that of sea-level rise. Much work has
therefore been done on the linear setback caused by a rise in sea-level. In order to get the full
picture of possible changes caused by sea-level rise, the secondary effects of a rising sea-level also
need to be considered. Sea-level rise could cause changes to the nearshore wave climate and could
have impacts such as coastal erosion and changes to the coastline shape. The primary objective of
this study was therefore to investigate the effects of sea-level rise on the nearshore wave climate
and, consequently, the coastline stability.
Other consequences of climate change considered in this study include increasing average wave
heights and a rotation of offshore wave directions. The many headland-bay beaches on the South
African coastline are generally in a state of dynamic equilibrium and find their planforms based on
the local wave climate. Changes to the wave climate may therefore disrupt the equilibrium shapes of
these bays. This study was therefore also aimed at investigating the effects of the changes to the
wave climate on the stability of headland-bay beaches.
The three consequences of climate change expected to affect the nearshore wave climate were
identified as (1) sea-level rise; (2) an increased wave height; and (3) changing offshore wave angles.
Although changes to storm frequency and intensity are also possible, the impacts of these changes
were not studied.
In order to assess the impacts of the three considered changes on a typical headland-bay beach, two
numerical models were set up for Mossel Bay – a headland-bay beach on the southern coast of
South Africa. The modelling approach included a wave transformation model to calculate nearshore
wave climates from offshore data and a coastline model to assess the stability of the bay under the
changed nearshore wave climates.
The model results indicated that the rising sea-level alone would cause changes in the nearshore
wave direction. These changes were shown to alter the longshore sediment transport regime such
that rotations are expected in the south-western corner and eastern end of Mossel Bay. These rotations do not include the cross-shore effects of inundation and erosion, as suggested by models
such as the Bruun Model.
The results for an increased offshore wave height were inconclusive. The southerly rotation in
offshore wave angles was shown to affect the nearshore wave angles. These changes affected the longshore transport regime such that the outward sediment transports were reduced. A minor
accretion resulted in the centre of the bay for a 1° southerly rotation in offshore wave angles. For a
2° rotation, the extent of accretion increased and shifted towards the eastern end of the bay,
primarily due to the dominance of south-westerly waves in the local wave climate.
A valuable observation was made regarding the current stability of Mossel Bay. Inter-tidal reefs are
present along three sections of the bay. These reefs protect the coastline such that the current bay
shape contains sharp bends between the reefs. Under a rising sea-level, however, the effect of the
reefs will become less pronounced. If a water level should be reached where these reefs become
less significant, the planform of the bay is expected to smooth out through a significant
redistribution of sediment. This smoothing effect was shown to cause erosion of the coastline in the
order of 80m near the town of Klein Brak River. / AFRIKAANSE OPSOMMING: Die verskeie gevolge van klimaatsverandering bied ‘n merkwaardige bedreiging vir ontwikkelings
naby die kus. Hierdie bedreigings sluit die versouting van varswaterbronne, kuserosie en
oorstromings in. Vir kusgebiede is seevlakstyging gereeld die effek van klimaatsverandering wat die
meeste kommer wek. Dus is heelwat navorsing rakende die direkte erosie as gevolg van
seevlakstyging reeds gedoen. Om die volle beeld van die gevolge van ‘n stygende seevlak te verkry, is
dit egter nodig om ook die sekondêre effekte hiervan in ag te neem. Seevlakstyging kan
veranderinge in die golfklimaat naby die kus veroorsaak, en kan impakte soos kuserosie en
veranderende baaivorms tot gevolg hê. Die primêre doel van hierdie studie is dus om die effek van
seevlakstyging op die golfklimaat by die kus en gevolglik die stabiliteit van die kuslyn, te ondersoek.
Benewens die styging van die seevlak word die effekte van groter gemiddelde golfhoogtes en die
rotasie van diepsee golfrigtings ook in hierdie studie ondersoek. Die vele landpunt-baaie (headlandbay
beaches) op die Suid-Afrikaanse kus is meestal in ‘n dinamiese ekwilibriumtoestand, waarvan die
vorm deur die lokale golfklimaat bepaal word. Veranderinge aan dié golfklimaat mag dus die
ekwilibrium vorms van sulke baaie versteur. Hierdie studie het dus ook die stabilititeit van landpuntbaaie
onder ‘n veranderende golfklimaat ondersoek.
Die drie gevolge van klimaatsverandering wat verwag word om die golfklimaat naby die kus te
beïnvloed is geïdentifiseer as (1) seevlakstyging; (2) vergrote golfhoogtes; en (3) veranderende
diepsee golfhoeke. Veranderinge aan die frekwensie en intensiteit van storms is ook moontlike
gevolge van klimaatsverandering, maar die impakte hiervan is nie in die studie ondersoek nie.
Twee numeriese modelle is toegepas om die impak van die drie bogenoemde gevolge op Mosselbaai
– ‘n tipiese landpunt-baai aan die suidkus van Suid-Afrika – te ondersoek. ‘n Golfmodel is ingespan
om die golfklimaat naby die kus te bepaal waarna ‘n kuslynmodel gebruik is om die stabiliteit van die
baai onder die veranderde golfklimaat te ondersoek.
Die resultate van die studie dui daarop dat die golfhoeke naby die kus beïnvloed word deur
seevlakstyging. Daar is aangetoon dat dié veranderinge die langsstroomvervoer sodanig sal verander
dat kuslynrotasies in die suid-westelike hoek asook die oostelike rand van Mosselbaai verwag word.
Hierdie rotasies sluit nie die lineêre landwaartse verplasing van die kuslyn as gevolg van erosie en
oorstroming in nie.
Die effek van vergrote golfhoogtes kon nie met akkuraatheid ondersoek word nie. Daar is wel gevind
dat die suidwaartse rotasie van diepsee golfhoeke rotasies in die golfklimaat naby die kus
veroorsaak. Hierdie rotasies verander die langsstroom sedimentvervoer sodanig dat die uitwaartse sedimentvervoer verminder word en ‘n klein opbou van sediment in die middel van die baai vir ‘n 1°
diepsee rotasie verwag word. Vir ‘n 2° suidwaartse rotasie is daar ‘n groter opbou van sediment wat
verder ooswaarts veplaas is. Die ooswaartse veplasing is primêr ‘n gevolg van die oorheersing van
suid-westelike golftoestande in die golfklimaat.
‘n Waardevolle gevolgtrekking rakende die huidige stabiliteit van Mosselbaai is ook gemaak. Langs
drie gedeeltes van die Mosselbaaise kus word riwwe in die gebied tussen hoog- en laagwater
aangetref. Hierdie riwwe beskerm die kus sodanig dat skerp kinkels in die vorm van die baai tussen
die riwwe gesien kan word. Wanneer die seevlak styg, word die beskermende effek van die riwwe
egter minder doeltreffend. Indien ‘n watervlak bereik word waar dié effek genoegsaam verminder is,
word daar verwag dat die baai deur ‘n merkwaardige verplasing van sediment die kinkels sal uitstryk.
Deur hierdie proses word erosie in die orde van 80m naby die dorp van Klein Brakrivier verwag.
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Reduction of seawall overtopping at the StrandRoux, George Bishop 03 1900 (has links)
Thesis (MScEng)--Stellenbosch University, 2013. / ENGLISH ABSTRACT: The Strand is located within False Bay and frequently encounters large quantities of wave overtopping over the coastal defences. This results in the damage of property and infrastructure and causes streets to be flooded. Physical modelling tests were done by a consultancy firm to determine a solution by making use of a recurve structure at the back of the beach.
This study is an expansion of the previous physical modelling that was done and focuses on several factors that were not tested by the consultancy firm that could have an influence on the overtopping rate and provide additional information on the recurve design. These tests were: (i) the effectiveness of the proposed recurve wall design in reducing overtopping was compared to a vertical wall; (ii) the influence that modifications to the beach profile such as the beach slope, beach width and beach level have on the overtopping rate; and (iii) the sensitivity of overtopping to changes in wave period was tested. The information gathered from these tests was used to propose a possible solution for the Strand.
Numerical modelling was done with Delft3D-Wave to determine the wave height at the back of the beach using a nested grid. The waves at the Strand are depth limited and therefore very sensitive to changes in water level. By altering the beach level the model showed how the significant wave height at the back of the beach changes. First estimates of overtopping were determined using the relevant empirical calculations from the EuroTop Manual 2007 for a vertical seawall. No estimate could be made for the recurve wall since it did not fall in the valid range of the equations. From the physical modelling it was found that the overtopping reduced significantly from a vertical to a recurve seawall by a factor of about 50% depending on the wall height. All the prediction methods tested proved to be accurate in estimating the overtopping when the ratio of freeboard to significant wave height was ≤1.83. For non-breaking wave conditions the beach profiles that were gently sloped (1:50) and wide produced more overtopping than the beach profiles that were steep (1:10) and narrow. Increasing the beach level only decreased the overtopping if the water depth was shallow enough to cause the waves to break before they reached the back of the beach. Overtopping was found to increase with longer wave periods until the wave period became too long and the waves broke offshore which resulted in the overtopping decreasing.
Possible solutions to overtopping were proposed based on two beach levels and the implementation of a recurve seawall. Revised crest levels for the wall were made along the length of the beach for both the 1:20 and 1:100 year water levels. / AFRIKAANSE OPSOMMING: Die Strand is in Valsbaai geleë en ervaar dikwels baie oorspoeling deur golwe bo-oor kusverdedigingswerke. Dit lei tot skade aan eiendom sowel as aan infrastruktuur en veroorsaak dat strate oorstroom. Fisiese modelleringstoetse is deur ’n konsultasiefirma gedoen om ’n oplossing te probeer vind deur van ’n teruggebuigde struktuur aan die agterkant van die strand gebruik te maak.
Hierdie studie is ’n uitbreiding van die vorige fisiese modellering wat gedoen is en fokus op verskeie faktore wat nie deur die konsultasiefirma getoets is nie. Dit kan moontlik ’n invloed op die oorspoelingstempo hê en verskaf bykomende inligting oor die ontwerp van die terugbuiging. Hierdie toetse is: (i) die doeltreffendheid van die voorgestelde ontwerp van die teruggebuigde strandmuur in die vermindering van oorspoeling word vergelyk met ’n vertikale muur; (ii) die invloed wat veranderinge aan die strandprofiel soos die helling van die strand, die wydte van die strand asook die strandvlak op die oorspoelingstempo het; en (iii) die sensitiwiteit van oorspoeling op veranderinge in golfperiode is getoets. Die inligting wat uit hierdie toetse verkry is, word gebruik om ’n moontlike oplossing vir die Strand voor te stel.
Numeriese modellering is met Delft3D-Wave gedoen om die golfhoogte aan die agterkant van die strand vas te stel deur van ’n genestelde ruitenet gebruik te maak. Die golwe by die Strand word deur diepte beperk en is dus baie sensitief vir veranderinge in die watervlak. Deur die strandvlakke te verander het die model getoon hoe die betekenisvolle golfhoogte aan die agterkant van die strand verander. Die eerste beramings van oorspoeling is bepaal deur van die relevante empiriese berekenings uit die EuroTop-handleiding 2007 vir ’n vertikale strandmuur gebruik te maak. Daar kon geen beraming vir die teruggebuigde muur gemaak word nie aangesien dit nie binne die geldige bereik van die vergelykings val nie. Uit die fisiese modellering is daar vasgestel dat oorspoeling noemenswaardig met ’n gemiddeld van ongeveer 50% verminder is, afhangend van die muurhoogte. Al die voorspellingmetodes wat getoets is was akkuraat in die beraming van die oorspoeling wanneer die verhouding van vryboord tot betekenisvolle golfhoogte ≤1.83 was. Vir nie-brekende golftoestande het strandprofiele met ’n lae helling (1:50) en wat wyd was meer oorspoeling tot gevolg gehad as strandprofiele wat steil (1:10) en nou was. ’n Verhoging in die strand se vlakke het die oorspoeling slegs verminder indien die diepte van die water vlak genoeg was om die golwe te laat breek voordat hulle die agterkant van die strand bereik het. Oorspoeling is gevind om te vermeeder met verlengde golflengte tot dat die golflengte só lank geword het dat die golwe in dieper water begin breek wat aanlieding tot verminderde oorspoeling gegee het. Daar word moontlike oplossings vir oorspoeling voorgestel gebaseer op twee strandvlakke en die implementering van ’n teruggebuigde strandmuur. Voorgestelde golfkruinvlakke vir die muur is al langs die lengte van die strand gemaak vir beide die 1:20- en 1:100-jaar watervlakke.
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Size-selective sediment transport and cross-shore profile evolution in the nearshore zoneSrisuwan, Chatchawin 12 November 2012 (has links)
Cross-shore bathymetric evolution in the nearshore zone often leads to threatening consequences such as beach erosion and shoreline retreat that concern the coastal community. A new, comprehensive cross-shore morphodynamic model was developed that can be used to describe and predict these phenomena. The study included both physical and numerical models that were designed to focus on the influence of sediment size characteristics on the cross-shore sediment transport process. For a profile equilibrium timescale, three types of beach profiles with different sediment mixtures were simulated in a small-scale, random-wave flume laboratory using erosive, storm, and accretive wave conditions. Dynamic relationships between the sediment grain sorting and beach profile changes were found to be evident as size-graded sediment fractions tended to relocate to different energetic zones along the cross-shore profiles. Existing phase-averaged wave and circulation models were utilized together with several new intra-wave modules for predicting important hydrodynamic parameters that were validated using the experimental data. A novel, multi-size sediment transport model was formulated to compute individual transport rates of size-graded sediment fractions while accounting for their interaction and non-linear size dependencies. The model was coupled with a new grain sorting model that resolves cross-shore grain sorting and vertical grain lamination. Compared to a traditional modeling approach, the new comprehensive model proved to offer superior modeling accuracy for both profile evolution and sediment grain size change. The use of the model is most advantageous for a condition with intensive grain sorting, a common scenario on a natural beach profile. Equilibrium beach profile is also better simulated by the model as size-graded fractions are predicted to relocate to different zones where they could withstand local hydrodynamics. Other new components that also help improve the modeling capability include the terms for wave-breaking and bed-slope effects, wave-crest sediment flux, and acceleration-induced bottom-shear stress. Besides superior profile modeling accuracy, sediment size characteristics and their spatial and temporal variations are also a useful set of information provided by the new model.
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Morphology, patterns and processes in the Oyster Bay headland bypass dunefield, South Africa / Investigation of the relationship between morphology, patterns and processes in a headland bypass dunefield, in the Eastern Cape, South AfricaMcConnachie, Lauren Bernyse January 2013 (has links)
Studies of the dunefield systems crossing the Cape St. Francis headland in the Eastern Cape have focused on the role that wind plays in sediment transfer in coastal dunefield systems, with limited consideration of the role of water. The aim of this study was to improve understanding of the morphology, processes and patterns within the Oyster Bay HBD system, focussing particularly on surface water and groundwater interactions and the role of surface water in sediment transfer across the dunefield system. An extensive field survey was conducted, to collect related data, complimented by spatial and temporal analysis of the study area using GIS. The key findings from this research were the apparent differences between the western and eastern regions of the dunefield with regard to specific drivers and the respective processes and responses. Wind is the major driver of change up to and across the crest of the dunefield. In the eastern region water (ground water, surface water and the Sand River System) is the primary agent of sediment flux through processes of aggregation and slumping as well as episodic events including debris flows. This study has highlighted a need for further quantitative studies that investigate the movement of sediment through dunefield systems such as this (where water is at or near the land surface). The paradigm that sediment flux is entirely due to wind is almost certainly simplistic, and deeper understanding of these systems is needed / Maiden name: Elkington, Lauren
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Analysis of a 10-year Nearshore Wave Database and its Implications to Littoral ProcessesMontoya, Luis Humberto 01 January 2014 (has links)
The variability of the nearshore wave climate is investigated via the analysis of over 10 years of Acoustic Doppler Current Profiler (ADCP) data from a gauge deployed at Melbourne Beach, FL. Examples of large yearly variability in the significant wave height, peak period, mean direction and energy distribution are found in the data. Estimates of the averaged spectra for the entire record show that the average wave energy is distributed almost symmetrically with the peak being close to shore-normal. It was expected that the peak would be shifted towards the north of shore-normal considering net north to south longshore sediment transport at this location. Further analysis of the directional spectra partitioned into three directional windows reveals that waves from the southeast (avg. Hmo = 0.78 m) are less energetic than those from the northeast (avg. Hmo = 0.87 m), but they arrive from the south 53% more often.
Additionally, energy-based significant wave height (Hmo), peak period (Tp) and mean period (Tmean) distributions are studied and modeled with notable success.
Radiation stress (Sxy) estimates are computed using both rigorous integration as well as parameter-based approximations. These two estimates are correlated but the parameter-based approximation over predicts Sxy by 42%, because this method assigns all the wave energy into one direction (Ruessink et al., 2001).
Finally, it is shown by the Sxy total average that the net longshore forcing at this location is indeed north to south, but yearly and seasonal variability were quite high. The results indicate that short-term wave records may not provide accurate information for planning purposes. For example, if only 3 months of data were collected at this site, there would be a 33% chance that the mean longshore forcing would be erroneously directed from south to north.
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