Feedback structure of cliff and shore platform morphodynamics
Feedback structure of cliff and shore platform morphodynamics
It has been suggested that studies of geomorphological systems should identify potential system feedbacks, determine their direction of influence, and assess their relative importance. In this paper we show how a core set of processes and feedback loops can be distilled from existing literature on rock coast morphodynamics. The structure has been represented using Causal Loop Diagrams and a methodology to estimate the strength of a single feedback loop is presented. The backwearing erosion rate (cliff horizontal erosion) has been found to be controlled by at least four feedback loops; three balancing (cliff toe wave energy depletion, ground-water pore pressure diminution and cliff deposit protection) and one positive loop (abrasion enhancement). The downwearing erosion rate (vertical erosion) has been found to be controlled by at least three balancing feedback loops (weathering limited, shear depletion, cover-protection). Mean sea level directly influences the downwearing rate, through the water depth relative to the wave base, and indirectly influences the backwearing erosion rate through the wave energy dissipation that determines the amount of energy reaching the cliff toe. The offshore wave non-linearity parameter is proposed to capture the complex interaction between waves and shore platform geometries. The strength of the cliff toe energy depletion loop is assessed by reasoning on its causal pathway and found to be O(?10?10 to ?10?4) for poorly lithified rock coasts. By understanding how the individual and overall feedback strengths are influenced by different future environmental and human intervention scenarios we could provide better assessment at the time scales needed for coastal management
1-17
Payo, A
755309ea-3c8a-4461-a533-d2fe25121d83
Hall, Jim W.
6084cd9f-ef4b-451c-8756-f0e8c14b26b5
Dickson, Mark E.
d9696a17-f1b8-4013-9755-82086ebcdb05
Walkden, Mike J.A.
cdd79138-35ce-4961-a413-cf4a9e9bdccc
1 October 2014
Payo, A
755309ea-3c8a-4461-a533-d2fe25121d83
Hall, Jim W.
6084cd9f-ef4b-451c-8756-f0e8c14b26b5
Dickson, Mark E.
d9696a17-f1b8-4013-9755-82086ebcdb05
Walkden, Mike J.A.
cdd79138-35ce-4961-a413-cf4a9e9bdccc
Payo, A, Hall, Jim W., Dickson, Mark E. and Walkden, Mike J.A.
(2014)
Feedback structure of cliff and shore platform morphodynamics.
Journal of Coastal Conservation, .
(doi:10.1007/s11852-014-0342-z).
Abstract
It has been suggested that studies of geomorphological systems should identify potential system feedbacks, determine their direction of influence, and assess their relative importance. In this paper we show how a core set of processes and feedback loops can be distilled from existing literature on rock coast morphodynamics. The structure has been represented using Causal Loop Diagrams and a methodology to estimate the strength of a single feedback loop is presented. The backwearing erosion rate (cliff horizontal erosion) has been found to be controlled by at least four feedback loops; three balancing (cliff toe wave energy depletion, ground-water pore pressure diminution and cliff deposit protection) and one positive loop (abrasion enhancement). The downwearing erosion rate (vertical erosion) has been found to be controlled by at least three balancing feedback loops (weathering limited, shear depletion, cover-protection). Mean sea level directly influences the downwearing rate, through the water depth relative to the wave base, and indirectly influences the backwearing erosion rate through the wave energy dissipation that determines the amount of energy reaching the cliff toe. The offshore wave non-linearity parameter is proposed to capture the complex interaction between waves and shore platform geometries. The strength of the cliff toe energy depletion loop is assessed by reasoning on its causal pathway and found to be O(?10?10 to ?10?4) for poorly lithified rock coasts. By understanding how the individual and overall feedback strengths are influenced by different future environmental and human intervention scenarios we could provide better assessment at the time scales needed for coastal management
Text
Payo_Hall_Dickson_Walkden_JCC_final_minorcorrected.pdf
- Accepted Manuscript
More information
Published date: 1 October 2014
Organisations:
Energy & Climate Change Group
Identifiers
Local EPrints ID: 381711
URI: http://eprints.soton.ac.uk/id/eprint/381711
ISSN: 1400-0350
PURE UUID: 86ceb2a5-5122-49a7-a44c-3fd90c3b535c
Catalogue record
Date deposited: 18 Sep 2015 13:23
Last modified: 22 Jul 2022 19:34
Export record
Altmetrics
Contributors
Author:
A Payo
Author:
Jim W. Hall
Author:
Mark E. Dickson
Author:
Mike J.A. Walkden
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics