The impact of sea-level rise on tidal characteristics around Australia
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Published:2019-02-15
Issue:1
Volume:15
Page:147-159
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ISSN:1812-0792
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Container-title:Ocean Science
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language:en
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Short-container-title:Ocean Sci.
Author:
Harker AlexanderORCID, Green J. A. Mattias, Schindelegger MichaelORCID, Wilmes Sophie-Berenice
Abstract
Abstract. An established tidal model, validated for present-day conditions, is used to
investigate the effect of large levels of sea-level rise (SLR) on tidal
characteristics around Australasia. SLR is implemented through a uniform
depth increase across the model domain, with a comparison between the
implementation of coastal defences or allowing low-lying land to flood. The
complex spatial response of the semi-diurnal M2 constituent does not
appear to be linear with the imposed SLR. The most predominant features of
this response are the generation of new amphidromic systems within the Gulf
of Carpentaria and large-amplitude changes in the Arafura Sea, to the north
of Australia, and within embayments along Australia's north-west coast.
Dissipation from M2 notably decreases along north-west Australia but is
enhanced around New Zealand and the island chains to the north. The diurnal
constituent, K1, is found to decrease in amplitude in the Gulf of
Carpentaria when flooding is allowed. Coastal flooding has a profound impact
on the response of tidal amplitudes to SLR by creating local regions of
increased tidal dissipation and altering the coastal topography. Our results
also highlight the necessity for regional models to use correct open boundary
conditions reflecting the global tidal changes in response to SLR.
Funder
Natural Environment Research Council Austrian Science Fund
Publisher
Copernicus GmbH
Subject
Cell Biology,Developmental Biology,Embryology,Anatomy
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