Modeling sorting dynamics of cohesive and non-cohesive sediments on intertidal flats under the effect of tides and wind waves
Modeling sorting dynamics of cohesive and non-cohesive sediments on intertidal flats under the effect of tides and wind waves
We extend a numerical model to explore the morphodynamics of intertidal flats, with a specific focus on the sorting dynamics of sand and mud. We investigate the effect of tidal currents, wind waves, sediment properties, external sediment supply, flocculation and initial bed composition on the cross-shore profile shape and sediment sorting of intertidal flats. Consistent with existing analytical theories and benchmark simplified numerical solutions, the equilibrium cross-shore profile of intertidal flats simulated by the extended model is convex-up when tidal currents dominate and it progressively becomes concave-up when the strength of wind waves increases. The equilibrium profile is influenced by the external sediment supply which can lead to the seaward advance of intertidal flats. In line with field observations, mud tends to deposit on the upper intertidal flats when wind waves are relatively weak, while sand is mainly distributed on the middle and lower tidal flats. When wind waves are strong, both sand and mud are more easily resuspended and eroded, resulting in a noticeably concave-up profile near the high water mark. The initial bed composition (e.g., percentage of mud and sand fractions) is also found to play an important role: the intertidal flat is more convex-up in a muddier environment. Numerical modeling demonstrates that sediment properties (e.g., critical shear stress for erosion, settling velocity) and flocculation can pronouncedly influence the sediment sorting dynamics by modifying the initiation threshold and the advection distance of entrained sediments. Application of the extended model to a natural study site indicates a qualitative agreement with field observations.
Cross-shore profile, Intertidal flats, Morphodynamics, Numerical modeling, Sediment sorting
76-91
Zhou, Zeng
f25e1390-6f07-4a32-9ebf-de15c07ded62
Coco, Giovanni
8a6c97e1-2a44-4f03-ad8d-e03dbc2908db
van der Wegen, Mick
d2a102db-0ab2-4563-a437-3f11f230d2c7
Gong, Zheng
8fc9bba8-c353-4445-b0ba-bc2cb6a6f24b
Zhang, Changkuan
dfdb560e-6606-4ba2-86be-f7068ef48393
Townend, Ian
f72e5186-cae8-41fd-8712-d5746f78328e
1 August 2015
Zhou, Zeng
f25e1390-6f07-4a32-9ebf-de15c07ded62
Coco, Giovanni
8a6c97e1-2a44-4f03-ad8d-e03dbc2908db
van der Wegen, Mick
d2a102db-0ab2-4563-a437-3f11f230d2c7
Gong, Zheng
8fc9bba8-c353-4445-b0ba-bc2cb6a6f24b
Zhang, Changkuan
dfdb560e-6606-4ba2-86be-f7068ef48393
Townend, Ian
f72e5186-cae8-41fd-8712-d5746f78328e
Zhou, Zeng, Coco, Giovanni, van der Wegen, Mick, Gong, Zheng, Zhang, Changkuan and Townend, Ian
(2015)
Modeling sorting dynamics of cohesive and non-cohesive sediments on intertidal flats under the effect of tides and wind waves.
Continental Shelf Research, 104, .
(doi:10.1016/j.csr.2015.05.010).
Abstract
We extend a numerical model to explore the morphodynamics of intertidal flats, with a specific focus on the sorting dynamics of sand and mud. We investigate the effect of tidal currents, wind waves, sediment properties, external sediment supply, flocculation and initial bed composition on the cross-shore profile shape and sediment sorting of intertidal flats. Consistent with existing analytical theories and benchmark simplified numerical solutions, the equilibrium cross-shore profile of intertidal flats simulated by the extended model is convex-up when tidal currents dominate and it progressively becomes concave-up when the strength of wind waves increases. The equilibrium profile is influenced by the external sediment supply which can lead to the seaward advance of intertidal flats. In line with field observations, mud tends to deposit on the upper intertidal flats when wind waves are relatively weak, while sand is mainly distributed on the middle and lower tidal flats. When wind waves are strong, both sand and mud are more easily resuspended and eroded, resulting in a noticeably concave-up profile near the high water mark. The initial bed composition (e.g., percentage of mud and sand fractions) is also found to play an important role: the intertidal flat is more convex-up in a muddier environment. Numerical modeling demonstrates that sediment properties (e.g., critical shear stress for erosion, settling velocity) and flocculation can pronouncedly influence the sediment sorting dynamics by modifying the initiation threshold and the advection distance of entrained sediments. Application of the extended model to a natural study site indicates a qualitative agreement with field observations.
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More information
Published date: 1 August 2015
Keywords:
Cross-shore profile, Intertidal flats, Morphodynamics, Numerical modeling, Sediment sorting
Identifiers
Local EPrints ID: 469406
URI: http://eprints.soton.ac.uk/id/eprint/469406
ISSN: 0278-4343
PURE UUID: 88bb674a-9821-44fc-a77e-256cd431324b
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Date deposited: 14 Sep 2022 16:46
Last modified: 18 Mar 2024 02:55
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Contributors
Author:
Zeng Zhou
Author:
Giovanni Coco
Author:
Mick van der Wegen
Author:
Zheng Gong
Author:
Changkuan Zhang
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