Marsh Equilibrium Theory

James T. Morris; Donald R. Cahoon; John C. Callaway; Christopher Craft; Scott C. Neubauer; Nathaniel B. Weston

doi:10.1017/9781316888933.009

7 - Marsh Equilibrium Theory

Implications for Responses to Rising Sea Level

from Part II - Marsh Dynamics

Published online by Cambridge University Press: 19 June 2021

Scott C. Neubauer and

Nathaniel B. Weston

Edited by

Duncan M. FitzGerald and

Zoe J. Hughes

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Duncan M. FitzGerald: Affiliation:
Boston University
Zoe J. Hughes: Affiliation:
Boston University

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Summary

The analysis presented here was motivated by an objective of describing the interactions between the physical and biological processes governing the responses of tidal wetlands to rising sea level and the ensuing equilibrium elevation. We define equilibrium here as meaning that the elevation of the vegetated surface relative to mean sea level (MSL) remains within the vertical range of tolerance of the vegetation on decadal time scales or longer. The equilibrium is dynamic, and constantly responding to short-term changes in hydrodynamics, sediment supply, and primary productivity. For equilibrium to occur, the magnitude of vertical accretion must be great enough to compensate for change in the rate of sea-level rise (SLR). SLR is defined here as meaning the local rate relative to a benchmark, typically a gauge. Equilibrium is not a given, and SLR can exceed the capacity of a wetland to accrete vertically.

Keywords

marsh equilibrium theory North Inlet SC vertical accretion organic production

Type: Chapter
Information: Salt Marshes
Function, Dynamics, and Stresses
, pp. 157 - 177

DOI: https://doi.org/10.1017/9781316888933.009 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2021

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