This study focuses on the impact of potential changes in the wind-wave climate on
shoreline change. The `one-line' model for medium to long-term prediction of coastline
evolution is employed. New analytical and numerical solutions of this important model are
described. Specifically: 1) original semi-analytical solutions are derived that relax the
unrealistic assumption of existing analytical work that a constant wave condition drives
shoreline change and, 2) a more general form of the one-line model is solved with a novel
application of the `Method of Lines'. Model input consists of 30-year nearshore wave
climate scenarios, corresponding to the `present' (1961-1990) and the future (2071-2100).
Winds from a high resolution, (12km x 12km), regional climate model, obtained offshore of
the south-central coast of England at a dense temporal resolution of 3 hours, are used to
develop the aforementioned wave climate scenarios, through hindcast and inshore wave
transformation. A hypothetical shoreline segment is adopted as a `benchmark' case for
comparisons. Monthly and seasonal statistics of output shoreline positions are generated
and assessedfo r relative changeso f `significance' between `present' and future. Different
degrees of evidence that such changes do exist are found. This study is the first application
of such high resolution climate model output to investigate climate change impact on
shoreline response. Major findings include: 1) shoreline changes of `significance' are
strongly linked to `significant' changes in future wave direction, 2) future changes appear
smaller for entire seasons than for individual months, 3) shoreline position variability is
often smaller in the future, 4) different climate model experiments produce diverging
results; however, general trends are largely similar.
The present study, at a fundamental level, offers analytical solutions of the 'oneline'
model that are closer to reality and a numerical solution that is of increased effciency..
At a practical level, it contributes to better understanding of the patterns of shoreline
response to changing offshore wave climate through: 1) the use of fast and straightforward
methods that can accommodate numerous climate scenarios without need for data
reduction, and 2) the development of a methodology for using climate model output for
coastal climate change impact assessment studies.
Date of Award | 2008 |
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Original language | English |
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Awarding Institution | |
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Mathematical modelling of shoreline evolution under climate change
Zacharioudaki, A. (Author). 2008
Student thesis: PhD