Dynamic allometry in coastal overwash morphology
Dynamic allometry in coastal overwash morphology
Allometry refers to a physical principle in which geometric (and/or metabolic) characteristics of an object or organism are correlated to its size. Allometric scaling relationships typically manifest as power laws. In geomorphic contexts, scaling relationships are a quantitative signature of organization, structure, or regularity in a landscape, even if the mechanistic processes responsible for creating such a pattern are unclear. Despite the ubiquity and variety of scaling relationships in physical landscapes, the emergence and development of these relationships tend to be difficult to observe – either because the spatial and/or temporal scales over which they evolve are so great or because the conditions that drive them are so dangerous (e.g. an extreme hazard event). Here, we use a physical experiment to examine dynamic allometry in overwash morphology along a model coastal barrier. We document the emergence of a canonical scaling law for length versus area in overwash deposits (washover). Comparing the experimental features, formed during a single forcing event, to 5 decades of change in real washover morphology from the Ria Formosa barrier system, in southern Portugal, we find differences between patterns of morphometric change at the event scale versus longer timescales. Our results may help inform and test process-based coastal morphodynamic models, which typically use statistical distributions and scaling laws to underpin empirical or semi-empirical parameters at fundamental levels of model architecture. More broadly, this work dovetails with theory for landscape evolution more commonly associated with fluvial and alluvial terrain, offering new evidence from a coastal setting that a landscape may reflect characteristics associated with an equilibrium or steady-state condition even when features within that landscape do not.
37–50
Lazarus, Eli
642a3cdb-0d25-48b1-8ab8-8d1d72daca6e
Davenport, Kirstin L.
60f0c3cd-6d2b-4d3f-81f5-1a7eefe50a1a
Matias, Ana
23980107-e740-41a3-b95e-228e423eafb4
21 January 2020
Lazarus, Eli
642a3cdb-0d25-48b1-8ab8-8d1d72daca6e
Davenport, Kirstin L.
60f0c3cd-6d2b-4d3f-81f5-1a7eefe50a1a
Matias, Ana
23980107-e740-41a3-b95e-228e423eafb4
Lazarus, Eli, Davenport, Kirstin L. and Matias, Ana
(2020)
Dynamic allometry in coastal overwash morphology.
Earth Surface Dynamics, 8, .
(doi:10.5194/esurf-8-37-2020).
Abstract
Allometry refers to a physical principle in which geometric (and/or metabolic) characteristics of an object or organism are correlated to its size. Allometric scaling relationships typically manifest as power laws. In geomorphic contexts, scaling relationships are a quantitative signature of organization, structure, or regularity in a landscape, even if the mechanistic processes responsible for creating such a pattern are unclear. Despite the ubiquity and variety of scaling relationships in physical landscapes, the emergence and development of these relationships tend to be difficult to observe – either because the spatial and/or temporal scales over which they evolve are so great or because the conditions that drive them are so dangerous (e.g. an extreme hazard event). Here, we use a physical experiment to examine dynamic allometry in overwash morphology along a model coastal barrier. We document the emergence of a canonical scaling law for length versus area in overwash deposits (washover). Comparing the experimental features, formed during a single forcing event, to 5 decades of change in real washover morphology from the Ria Formosa barrier system, in southern Portugal, we find differences between patterns of morphometric change at the event scale versus longer timescales. Our results may help inform and test process-based coastal morphodynamic models, which typically use statistical distributions and scaling laws to underpin empirical or semi-empirical parameters at fundamental levels of model architecture. More broadly, this work dovetails with theory for landscape evolution more commonly associated with fluvial and alluvial terrain, offering new evidence from a coastal setting that a landscape may reflect characteristics associated with an equilibrium or steady-state condition even when features within that landscape do not.
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esurf-8-37-2020
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Accepted/In Press date: 13 December 2019
Published date: 21 January 2020
Identifiers
Local EPrints ID: 452049
URI: http://eprints.soton.ac.uk/id/eprint/452049
ISSN: 2196-6311
PURE UUID: 490c6ea3-357e-4acb-b162-c001a8acb034
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Date deposited: 09 Nov 2021 17:34
Last modified: 17 Mar 2024 03:44
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Author:
Kirstin L. Davenport
Author:
Ana Matias
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