Recent Acceleration of Wetland Accretion and Carbon Accumulation Along the U.S. East Coast

Author:

Weston Nathaniel B.1ORCID,Rodriguez Elise1,Donnelly Brian1,Solohin Elena2,Jezycki Kristen1,Demberger Sandra1,Sutter Lori A.3,Morris James T.4ORCID,Neubauer Scott C.5ORCID,Craft Christopher B.2

Affiliation:

1. Department of Geography and the Environment Villanova University Villanova PA USA

2. O’Neill School of Public and Environmental Affairs Indiana University Bloomington IN USA

3. Department of Biology and Marine Biology University of North Carolina Wilmington Wilmington NC USA

4. Department of Biological Sciences University of South Carolina Columbia SC USA

5. Department of Biology Virginia Commonwealth University Richmond VA USA

Abstract

AbstractThe long‐term stability of coastal wetlands is determined by interactions among sea level, plant primary production, sediment supply, and wetland vertical accretion. Human activities in watersheds have significantly altered sediment delivery from the landscape to the coastal ocean, with declines along much of the U.S. East Coast. Tidal wetlands in coastal systems with low sediment supply may have limited ability to keep pace with accelerating rates of sea‐level rise (SLR). Here, we show that rates of vertical accretion and carbon accumulation in nine tidal wetland systems along the U.S. East Coast from Maine to Georgia can be explained by differences in the rate of relative SLR (RSLR), the concentration of suspended sediments in the rivers draining to the coast, and temperature in the coastal region. Further, we show that rates of vertical accretion have accelerated over the past century by between 0.010 and 0.083 mm yr−2, at roughly the same pace as the acceleration of global SLR. We estimate that rates of carbon sequestration in these wetland soils have accelerated (more than doubling at several sites) along with accelerating accretion. Wetland accretion and carbon accumulation have accelerated more rapidly in coastal systems with greater relative RSLR, higher watershed sediment availability, and lower temperatures. These findings suggest that the biogeomorphic feedback processes that control accretion and carbon accumulation in these tidal wetlands have responded to accelerating RSLR, and that changes to RSLR, watershed sediment supply, and temperature interact to determine wetland vulnerability across broad geographic scales.

Funder

National Science Foundation

Publisher

American Geophysical Union (AGU)

Subject

Earth and Planetary Sciences (miscellaneous),General Environmental Science

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