Morphodynamic adaptation of a tidal basin to centennial sea-level rise: The importance of lateral expansion
Morphodynamic adaptation of a tidal basin to centennial sea-level rise: The importance of lateral expansion
Global climate changes have accelerated sea-level rise (SLR), which exacerbates the risks of coastal flooding and erosion. It is of practical interest to understand the long-term hydro-morphodynamic adaptation of coastal systems to SLR at a century time scale. In this work we use a numerical model to explore morphodynamic evolution of a schematized tidal basin in response to SLR of 0.25–2.0 m over 100 years with special emphasis on the impact of lateral basin expansion. Starting from a sloped initial bed, morphodynamic development of the system leads to the formation of alternating bars and meandering channels inside the tidal basin and an ebb-tidal delta extending seaward from the basin. Imposing rising sea level causes progressive inundation of the low-lying floodplains, found along the basin margins, inducing an increase in basin plain area and tidal prism, as well as intertidal area and storage volume. Although the overall channel-shoal structure persists under SLR, lateral shoreline expansion alters the basin hypsometry, leading to enhanced sediment export. The newly-submerged floodplains partly erode, supplying sediment to the system for spatial redistribution, hence buffering the impact of SLR. The vertical accretion rate of the tidal flats inside the tidal basin lags behind the rate of SLR. However, lateral shoreline migration under SLR creates new intertidal flats, compensating intertidal flat loss in the original basin. In contrast, a constrained tidal basin without low-lying floodplains is subject to profound drowning and tidal flat losses under SLR. Overall, the model results suggest that an unconstrained tidal system allowing lateral shoreline migration has buffering capacity for alleviating the drowning impact of SLR by evolving new intertidal areas, sediment redistribution and morphodynamic adjustment. These findings suggest that preserving tidal flats located along the margins of tidal basins (instead of reclaiming them) sustains the system's resilience to SLR.
Accommodation space, Morphodynamic modeling, Sea-level rise, Tidal basin
104494
Guo, Leicheng
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Xu, Fan
a74a50aa-98c4-4457-a767-f0fe8820c535
Van Der Wegen, Mick
d2a102db-0ab2-4563-a437-3f11f230d2c7
Townend, Ian
f72e5186-cae8-41fd-8712-d5746f78328e
Wang, Zheng Bing
0bf73ba6-eed4-4ebe-8175-929d35912e3d
He, Qing
94baedd4-45f0-436e-83d4-4e2ebcd1bec3
1 September 2021
Guo, Leicheng
713f7dde-d88a-4f2c-9c66-7f9c6978ceb0
Xu, Fan
a74a50aa-98c4-4457-a767-f0fe8820c535
Van Der Wegen, Mick
d2a102db-0ab2-4563-a437-3f11f230d2c7
Townend, Ian
f72e5186-cae8-41fd-8712-d5746f78328e
Wang, Zheng Bing
0bf73ba6-eed4-4ebe-8175-929d35912e3d
He, Qing
94baedd4-45f0-436e-83d4-4e2ebcd1bec3
Guo, Leicheng, Xu, Fan, Van Der Wegen, Mick, Townend, Ian, Wang, Zheng Bing and He, Qing
(2021)
Morphodynamic adaptation of a tidal basin to centennial sea-level rise: The importance of lateral expansion.
Continental Shelf Research, 226, , [104494].
(doi:10.1016/j.csr.2021.104494).
Abstract
Global climate changes have accelerated sea-level rise (SLR), which exacerbates the risks of coastal flooding and erosion. It is of practical interest to understand the long-term hydro-morphodynamic adaptation of coastal systems to SLR at a century time scale. In this work we use a numerical model to explore morphodynamic evolution of a schematized tidal basin in response to SLR of 0.25–2.0 m over 100 years with special emphasis on the impact of lateral basin expansion. Starting from a sloped initial bed, morphodynamic development of the system leads to the formation of alternating bars and meandering channels inside the tidal basin and an ebb-tidal delta extending seaward from the basin. Imposing rising sea level causes progressive inundation of the low-lying floodplains, found along the basin margins, inducing an increase in basin plain area and tidal prism, as well as intertidal area and storage volume. Although the overall channel-shoal structure persists under SLR, lateral shoreline expansion alters the basin hypsometry, leading to enhanced sediment export. The newly-submerged floodplains partly erode, supplying sediment to the system for spatial redistribution, hence buffering the impact of SLR. The vertical accretion rate of the tidal flats inside the tidal basin lags behind the rate of SLR. However, lateral shoreline migration under SLR creates new intertidal flats, compensating intertidal flat loss in the original basin. In contrast, a constrained tidal basin without low-lying floodplains is subject to profound drowning and tidal flat losses under SLR. Overall, the model results suggest that an unconstrained tidal system allowing lateral shoreline migration has buffering capacity for alleviating the drowning impact of SLR by evolving new intertidal areas, sediment redistribution and morphodynamic adjustment. These findings suggest that preserving tidal flats located along the margins of tidal basins (instead of reclaiming them) sustains the system's resilience to SLR.
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Morphodynamic adaptation of a tidal basin ...
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Accepted/In Press date: 7 July 2021
Published date: 1 September 2021
Additional Information:
Funding Information:
This work is supported by the Ministry of Science and Technology, P.R. China (MOST) (No. 2017YFE0107400 ; 2016YFE0133700 ), Natural Science Foundation of China (Nos. 51739005 ; U2040216 ; 41876091 ), and the Science and Technology Commission of Shanghai Municipality (Nos. 19QA1402900 ; 20DZ1204700 ).
Publisher Copyright:
© 2021 Elsevier Ltd
Copyright:
Copyright 2021 Elsevier B.V., All rights reserved.
Keywords:
Accommodation space, Morphodynamic modeling, Sea-level rise, Tidal basin
Identifiers
Local EPrints ID: 450768
URI: http://eprints.soton.ac.uk/id/eprint/450768
ISSN: 0278-4343
PURE UUID: f4b0a36a-1d78-410c-80b6-750b4ec394a0
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Date deposited: 10 Aug 2021 16:33
Last modified: 17 Mar 2024 06:44
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Contributors
Author:
Leicheng Guo
Author:
Fan Xu
Author:
Mick Van Der Wegen
Author:
Zheng Bing Wang
Author:
Qing He
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