No Cover Image

Journal article 565 views 62 downloads

Saltmarsh Resilience to Periodic Shifts in Tidal Channels

Cai Ladd Orcid Logo, Mollie Frances Duggan-Edwards, Jordi F. Pagès, Martin Wiggers Skov

Frontiers in Marine Science, Volume: 8

Swansea University Author: Cai Ladd Orcid Logo

  • 64489.pdf

    PDF | Version of Record

    © 2021 Ladd, Duggan-Edwards, Pagès and Skov. Distributed under the terms of a Creative Commons Attribution 4.0 License (CC BY 4.0).

    Download (7.02MB)

Abstract

Resilience of coastal ecosystems to climate change is largely determined by the interaction between plants and the surrounding tidal environment. Research has tended to focus on processes operating at the local scale to explain resilience mechanisms, overlooking potentially important landscape-scale...

Full description

Published in: Frontiers in Marine Science
ISSN: 2296-7745
Published: Frontiers Media SA 2021
Online Access: Check full text

URI: https://cronfa.swan.ac.uk/Record/cronfa64489
Tags: Add Tag
No Tags, Be the first to tag this record!
Abstract: Resilience of coastal ecosystems to climate change is largely determined by the interaction between plants and the surrounding tidal environment. Research has tended to focus on processes operating at the local scale to explain resilience mechanisms, overlooking potentially important landscape-scale processes and patterns. We show from aerial images spanning 67 years across 3 estuaries that saltmarsh loss was compensated by expansion elsewhere in the estuary when tidal channels shifted position. Compensatory expansion rates were as high as 6 m/yr. This phenomenon of “geomorphic compensation” represents a hitherto overlooked large-scale self-organizing pattern that facilitates the long-term persistence of marshes in estuaries. The geomorphic compensation pattern likely also occurs in other hydrological systems including mangrove forests, and seagrass meadows, and river islands. Compensatory erosion-expansion patterns occurred at the same time as net marsh extent increased by between 120 and 235% across all three estuaries. Marsh expansion mostly occurred in the lower parts of each estuary, where channel migration and compensatory expansion was less evident. Patterns of geomorphic compensation therefore appear to operate at discrete spatio-temporal scales, nested within a hierarchy of coastal morphodynamic processes that govern longer-term patterns of either net marsh gain or loss. Coastal ecosystem resilience can therefore only be fully appreciated when examining erosion and expansion patterns at both local and landscape scales. The intrinsic dynamics of marshes described here have important implications for the long-term delivery of ecosystem services.
Keywords: Coastal biogeomorphology, ecosystem resilience, scale-dependence, saltmarsh edge, tidal channelmigration, sheltered macrotidal estuaries, ecosystem services
College: Faculty of Science and Engineering
Funders: This work was supported by the Coleg Cymraeg Cenedlaethol (Ysgoloriaethau Ymchwil), the Welsh Government and Higher Education Funding Council for Wales (Sêr Cymru National Research Network for Low Carbon, Energy and Environment), the Natural Environment Research Council (C-SIDE Project) (Grant No. NE/R010846/1), and the United Kingdom Research and Innovation Global Challenges Research Fund (Living Deltas Research Hub) (Grant No. NE/S008926/1).