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SMITH, A. M., MATHER, A. A., BUNDY, S. C., COOPER, J. A. G., GUASTELLA, L. A., RAMSAY, P. J., THERON, A. (2010) Contrasting styles of swell-driven coastal erosion: examples from KwaZulu-Natal, South Africa. Geological Magazine, 147 (6) 940-953 doi:10.1017/s0016756810000361

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Reference TypeJournal (article/letter/editorial)
TitleContrasting styles of swell-driven coastal erosion: examples from KwaZulu-Natal, South Africa
JournalGeological Magazine
AuthorsSMITH, A. M.Author
MATHER, A. A.Author
BUNDY, S. C.Author
COOPER, J. A. G.Author
GUASTELLA, L. A.Author
RAMSAY, P. J.Author
THERON, A.Author
Year2010 (November)Volume147
Issue6
PublisherCambridge University Press (CUP)
DOIdoi:10.1017/s0016756810000361Search in ResearchGate
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Mindat Ref. ID260478Long-form Identifiermindat:1:5:260478:1
GUID0
Full ReferenceSMITH, A. M., MATHER, A. A., BUNDY, S. C., COOPER, J. A. G., GUASTELLA, L. A., RAMSAY, P. J., THERON, A. (2010) Contrasting styles of swell-driven coastal erosion: examples from KwaZulu-Natal, South Africa. Geological Magazine, 147 (6) 940-953 doi:10.1017/s0016756810000361
Plain TextSMITH, A. M., MATHER, A. A., BUNDY, S. C., COOPER, J. A. G., GUASTELLA, L. A., RAMSAY, P. J., THERON, A. (2010) Contrasting styles of swell-driven coastal erosion: examples from KwaZulu-Natal, South Africa. Geological Magazine, 147 (6) 940-953 doi:10.1017/s0016756810000361
In(2010, November) Geological Magazine Vol. 147 (6) Cambridge University Press (CUP)
Abstract/NotesAbstractDuring 2006–2007, the KwaZulu-Natal coast of South Africa was exposed to several large swell events (Ho > 3 m), near the peak of the lunar nodal cycle, causing shoreline recession. The largest swell (Hs = 8.5 m) struck the coast on the March equinox (18th–20th) and generated a strong storm-return flow. Observations made before, during and after record dramatic coastal erosion (shoreline recession of up to 40 m and substantial property damage). This swell event removed the semi-continuous nearshore bar system and ‘conditioned’ the coast such that lesser subsequent swell events accomplished much greater amounts of coastal erosion than expected (up to 100 m at certain erosion hotspots) because waves reached the coast without significant energy dissipation. Subsequent bar generation rebuilt the inshore bars within six months. The styles of erosion during the March ’07 event and other 2007 swells were markedly different. Lesser swells are focused by headlands and result in megarip development and activation of erosion hotspots. The March ’07 event still-water level was raised (equinoctial spring high tide and a storm surge of 0.33–0.45 m) to a level that rendered most headlands (and erosion hotspots) ineffective and resulted in laterally extensive erosion of soft shorelines. Results record cumulative effects of successive swell events on coastal behaviour that proved to be critical in enabling erosion to proceed at rapid rates after the coast had been initially destabilized. Unlike hurricanes and tsunamis, surges associated with swell events are relatively minor and therefore extensive erosion is linked with high lunar tides. There is circumstantial evidence that swell-induced erosion follows the broad 18.6 yr lunar nodal tidal cycle when the chances of large swells coinciding with high water levels are increased.

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Guastella, Lisa A., Smith, Alan M. (2014) Coastal dynamics on a soft coastline from serendipitous webcams: KwaZulu-Natal, South Africa. Estuarine, Coastal and Shelf Science, 150. 76-85 doi:10.1016/j.ecss.2013.12.009
Cooper, J. Andrew G., Green, Andrew N. (2016) Geomorphology and preservation potential of coastal and submerged aeolianite: Examples from KwaZulu-Natal, South Africa. Geomorphology, 271. 1-12 doi:10.1016/j.geomorph.2016.07.028
Smith, A.M., Guastella, L.A., Botes, Z.A., Bundy, S.C., Mather, A.A. (2014) Forecasting cyclic coastal erosion on a multi-annual to multi-decadal scale: Southeast African coast. Estuarine, Coastal and Shelf Science, 150. 86-91 doi:10.1016/j.ecss.2013.12.010
LUTCHMIAH, J. (1999) SOIL EROSION IN THE CENTRAL MIDLANDS OF KWAZULU-NATAL: A COMPARATIVE STUDY. South African Geographical Journal, 81 (3). 143-147 doi:10.1080/03736245.1999.9713674
Moodley, M., Johnston, M. A., Hughes, J. C., Titshall, L. W. (2004) Effects of a water treatment residue, lime, gypsum, and polyacrylamide on the water retention and hydraulic conductivity of two contrasting soils under field conditions in KwaZulu-Natal, South Africa. Soil Research, 42 (3). 273pp. doi:10.1071/sr03045
Green, A. N., Flemming, B. W., Cooper, J. A. G., Wanda, T. F. (2022) Bedform evolution and dynamics of a geostrophic current-swept shelf, northern KwaZulu-Natal, South Africa. Geo-Marine Letters, 42 (1) doi:10.1007/s00367-021-00722-7
Cawthra, H.C., Neumann, F.H., Uken, R., Smith, A.M., Guastella, L.A., Yates, A. (2012) Sedimentation on the narrow (8km wide), oceanic current-influenced continental shelf off Durban, Kwazulu-Natal, South Africa. Marine Geology, 323. 107-122 doi:10.1016/j.margeo.2012.08.001
HEIDUK, ANNEMARIE, CROUCH, NEIL R., STYLES, DAVID G.A. (2023) Ceropegia gilboaensis (Apocynaceae), a new species from the Midlands of KwaZulu-Natal, South Africa. Phytotaxa, 591 (2) 125-136 doi:10.11646/phytotaxa.591.2.4
Gray, J., Theron, J. N., Boucot, A. J. (1986) Age of the Cedarberg Formation, South Africa and early land plant evolution. Geological Magazine, 123 (4) 445-454 doi:10.1017/s0016756800033537
Green, A. N., Flemming, B. W., Cooper, J. A. G., Wanda, T. F. (2022) Correction to: Bedform evolution and dynamics of a geostrophic current‑swept shelf, northern KwaZulu‑Natal, South Africa. Geo-Marine Letters, 42 (1) doi:10.1007/s00367-022-00728-9
Pile, Kerry (1996) Soil erosion, policy and people's perceptions in a rural community in KwaZulu-Natal, South Africa. GeoJournal, 39 (1) doi:10.1007/bf00174929
 
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