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Spatial and temporal analysis of extreme storm-tide and skew-surge events around the coastline of New Zealand

Spatial and temporal analysis of extreme storm-tide and skew-surge events around the coastline of New Zealand
Spatial and temporal analysis of extreme storm-tide and skew-surge events around the coastline of New Zealand
Coastal flooding is a major global hazard, yet few studies have examined the spatial and temporal characteristics of extreme sea level and associated coastal flooding. Here we analyse sea-level records around the coast of New Zealand (NZ) to quantify extreme storm-tide and skew-surge frequency and magnitude. We identify the relative magnitude of sea-level components contributing to 85 extreme sea level and 135 extreme skew-surge events recorded in NZ since 1900. We then examine the spatial and temporal clustering of these extreme storm-tide and skew-surge events and identify typical storm tracks and weather types associated with the spatial clusters of extreme events. We find that most extreme storm tides were driven by moderate skew surges combined with high perigean spring tides. The spring–neap tidal cycle, coupled with a moderate surge climatology, prevents successive extreme storm-tide events from happening within 4–10 d of each other, and generally there are at least 10 d between extreme storm-tide events. This is similar to findings from the UK (Haigh et al., 2016), despite NZ having smaller tides. Extreme events more commonly impacted the east coast of the North Island of NZ during blocking weather types, and the South Island and west coast of the North Island during trough weather types. The seasonal distribution of both extreme storm-tide and skew-surge events closely follows the seasonal pattern of mean sea-level anomaly (MSLA) – MSLA was positive in 92 % of all extreme storm-tide events and in 88 % of all extreme skew-surge events. The strong influence of low-amplitude (−0.06 to 0.28 m) MSLA on the timing of extreme events shows that mean sea-level rise (SLR) of similarly small height will drive rapid increases in the frequency of presently rare extreme sea levels. These findings have important implications for flood management, emergency response and the insurance sector, because impacts and losses may be correlated in space and time.
1684-9981
783–796
Stephens, Scott A.
136d9d51-cab6-4595-b982-7fb7be284b76
Bell, Robert G.
cfdd075f-7cde-499f-9021-86294bcef362
Haigh, Ivan
945ff20a-589c-47b7-b06f-61804367eb2d
Stephens, Scott A.
136d9d51-cab6-4595-b982-7fb7be284b76
Bell, Robert G.
cfdd075f-7cde-499f-9021-86294bcef362
Haigh, Ivan
945ff20a-589c-47b7-b06f-61804367eb2d

Stephens, Scott A., Bell, Robert G. and Haigh, Ivan (2020) Spatial and temporal analysis of extreme storm-tide and skew-surge events around the coastline of New Zealand. Natural Hazards and Earth System Sciences, 20 (3), 783–796, [42]. (doi:10.5194/nhess-20-783-2020).

Record type: Article

Abstract

Coastal flooding is a major global hazard, yet few studies have examined the spatial and temporal characteristics of extreme sea level and associated coastal flooding. Here we analyse sea-level records around the coast of New Zealand (NZ) to quantify extreme storm-tide and skew-surge frequency and magnitude. We identify the relative magnitude of sea-level components contributing to 85 extreme sea level and 135 extreme skew-surge events recorded in NZ since 1900. We then examine the spatial and temporal clustering of these extreme storm-tide and skew-surge events and identify typical storm tracks and weather types associated with the spatial clusters of extreme events. We find that most extreme storm tides were driven by moderate skew surges combined with high perigean spring tides. The spring–neap tidal cycle, coupled with a moderate surge climatology, prevents successive extreme storm-tide events from happening within 4–10 d of each other, and generally there are at least 10 d between extreme storm-tide events. This is similar to findings from the UK (Haigh et al., 2016), despite NZ having smaller tides. Extreme events more commonly impacted the east coast of the North Island of NZ during blocking weather types, and the South Island and west coast of the North Island during trough weather types. The seasonal distribution of both extreme storm-tide and skew-surge events closely follows the seasonal pattern of mean sea-level anomaly (MSLA) – MSLA was positive in 92 % of all extreme storm-tide events and in 88 % of all extreme skew-surge events. The strong influence of low-amplitude (−0.06 to 0.28 m) MSLA on the timing of extreme events shows that mean sea-level rise (SLR) of similarly small height will drive rapid increases in the frequency of presently rare extreme sea levels. These findings have important implications for flood management, emergency response and the insurance sector, because impacts and losses may be correlated in space and time.

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Accepted/In Press date: 10 February 2020
Published date: 24 March 2020
Additional Information: Funding Information: Financial support. This research has been supported by the New Zealand Ministry of Business, Innovation and Employment (Strategic Science Investment Fund projects CAVA1904 and CARH2002 – National Institute of Water and Atmospheric Research). Publisher Copyright: © 2020 Author(s).

Identifiers

Local EPrints ID: 439141
URI: http://eprints.soton.ac.uk/id/eprint/439141
ISSN: 1684-9981
PURE UUID: 2af4a007-86c9-44d8-9b57-ba8b019caf43
ORCID for Ivan Haigh: ORCID iD orcid.org/0000-0002-9722-3061

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Date deposited: 06 Apr 2020 16:30
Last modified: 06 Jun 2024 01:44

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Contributors

Author: Scott A. Stephens
Author: Robert G. Bell
Author: Ivan Haigh ORCID iD

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