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Effects of Marsh Edge Erosion in Coupled Barrier Island‐Marsh Systems and Geometric Constraints on Marsh Evolution
Author(s) -
Lauzon Rebecca,
Murray A. Brad,
Moore Laura J.,
Walters David C.,
Kirwan Matthew L.,
Fagherazzi Sergio
Publication year - 2018
Publication title -
journal of geophysical research: earth surface
Language(s) - English
Resource type - Journals
eISSN - 2169-9011
pISSN - 2169-9003
DOI - 10.1029/2017jf004530
Subject(s) - marsh , progradation , overwash , salt marsh , sediment , geology , erosion , wetland , hydrology (agriculture) , accretion (finance) , environmental science , barrier island , oceanography , geomorphology , structural basin , ecology , sedimentary depositional environment , geotechnical engineering , physics , astrophysics , shore , biology
Previous results show that overwash provides an important sediment source to back‐barrier marshes, sustaining a narrow marsh state under conditions in which marsh drowning would otherwise occur. We expand the coupled barrier island‐marsh evolution model GEOMBEST+ to explore the effects of wind waves on back‐barrier marshes. We find that the addition of marsh edge erosion leads to wider, more resilient marshes and that horizontal erosion of the marsh edge is a more efficient sediment source than vertical erosion of the marsh surface as it drowns. Where marshes and bays are vertically keeping up with sea level, and the net rate of sediment imported to (or exported from) the basin is known, the rate of marsh edge erosion or progradation can be predicted knowing only the present basin geometry, sea level rise rate, and the net rate of sediment input (without considering the erosion or progradation mechanisms). If the rate of sediment input/export is known, this relationship applies whether sediment exchange with the open ocean is negligible (as in basins dominated by riverine sediment input) or is significant (including the loss of sediment remobilized by waves in the bay). Analysis of these results reveals that geometry and stratigraphy can exert a first‐order control on back‐barrier marsh evolution and on the marsh‐barrier island system as a whole and provides new insights into the resilience of back‐barrier marshes and on the interconnectedness of the barrier‐marsh system.