Spatial data collected over 3 years is presented to assess the extent of morphological
variability under seasonal and storm waves at four high-energy macrotidal beaches. A
novel approach is adopted to identify and classify the beach response which is used to
assess the relative stability of the system to changes in the dominant forcing conditions.
Field measurements and modelling simulations using XBeach provide further support
for a storm dominated system exhibiting relative stability.
Morphologically the beaches range from dissipative to intermediate and are
characterised by low tide bar/rip morphology which plays a key role in the nearshore
dynamics and beach safety. Located in the north coast of Cornwall the sites are exposed
to high-energy waves that dominate the stability and behaviour of beaches in this region.
The growing need for marine renewable energy in the UK has led to the deployment of
a Wave Hub on the seabed off the north coast of Cornwall, designed to provide grid
connection for wave energy devices (WECs). As a unique development much has been
done to address concerns over potential impacts cause by arrays of WECs during its
construction and operational lifetime; these predicted impacts include changes in the
quality of waves for surfing and effects on the beach dynamics which determines beach
safety through the presence of bar/rip features.
In this thesis three years of monthly topographic surveys were collected from beaches in
the proposed Wave Hub shadow zone to assess their morphodynamic variability. Realtime
kinematic (RTK) GPS surveys were undertaken using an all-terrain vehicle to
measure the three dimensional (3D) morphology at four beaches (Perranporth, Chapel
Porth, Porthtowan and Gwithian) situated along a 23 km stretch of the north Cornish
coast. In addition nearshore wave data, in-situ hydrodynamic measurements, local tide
gauges and Argus video data allowed detailed analysis of process-response mechanisms
for long term (yearly); seasonal (monthly); storm (weekly/daily); and tidal (hourly)
morphological behaviour.
Of particular interest was the degree to which the beaches displayed bar/rip morphology,
characterised by the three dimensionality (3D) of beach response, which determines
wave breaking and affects beach safety. Using a combination of measured shoreline
variability and empirical beach classification schemes, the response to changes in the
wave conditions at each beach have been assessed. The sites exhibited net long term
accretion derived from the intertidal beach volume. Throughout the survey period intersite
similarity in beach response was observed in response to storm waves, yet coupling
between the seasonal wave climate and the beach morphology was not evident at any of
the sites, due to the dominance of recovery phases following storm events. The role of
increased wave conditions (exceeding Hs=4 m) during sustained storm events (> 50 hrs)
led to offshore transport from the beach face to the subtidal bar region. Post-storm
recovery was characterised by onshore transport and the development of substantial 3D
low tide morphology. Under normal wave conditions (Hs=1.6 m) the dominant 3D features smoothed out as channels in-filled and bars reduced over a period of 2-3
months. This cyclicity was observed on ~3 occasions at the northern sites, while
Gwithian remained more stable throughout; reflecting the more sheltered position of the
beach. Overall the beaches exhibited a significant storm dominated morphological
response cycle, unlike the more familiar winter/summer seasonal response.
Nearshore bar behaviour at Perranporth and Porthtowan, assessed using ARGUS images,
was dominated by offshore migration (ca.20 m/yr) following closely the net intertidal
accretion, while bar shape exhibited changes over monthly periods. Intensive field
studies of morphological change, nearshore current flows and surf zone wave conditions
were undertaken at Porthtowan during small swell dominated waves and large energetic
storm conditions in May and October 2010 respectively. The field data highlighted
accretionary response under small swell dominated waves, and strong offshore directed
undertow flows (0.5 m/s-1) during erosive energetic conditions (>Hs = 4m) which were
then related to the monthly surveys. These results were applied to XBeach model
simulations which helped further identify the importance of antecedent morphology and
the complexities of intertidal geology in controlling beach response.
The study provides the longest continuous record of beach morphology dynamics for
macrotidal energetic sites and provides a valuable addition to work in this field. The
dominance of storm driven morphological response was clear with highly threedimensional
morphology developing under post storm conditions and continued beach
evolution driven by the seasonal conditions. Antecedent morphology was found to be a
key element of beach response with geological control an additional component. The
projected reduction in wave conditions due to the Wave Hub and the natural variability
observed indicates the sites are unlikely to shift significantly from their current dynamic
state in response to the Wave Hub, and as such the potential impact on nearshore and
beach dynamics is minimal.
Date of Award | 2012 |
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Original language | English |
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Awarding Institution | |
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Supervisor | Paul Russell (Other Supervisor) |
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- Macrotidal
- Cornwall
- Morphological change
MORPHOLOGICAL RESPONSE OF HIGH-ENERGY MACROTIDAL BEACHES
Poate, T. (Author). 2012
Student thesis: PhD