Abstract

Coastal dunes arise from feedbacks between vegetation and sediment supply. Species-specific differences in plant functional morphology affect sand capture and dune shape. In this study, we build on research showing a relationship between dune grass species and dune geomorphology on the US central Atlantic Coast. This study seeks to determine the ways in which four co-occurring dune grass species (Ammophila breviligulata, Panicum amarum, Spartina patens, Uniola paniculata) differ in their functional morphology and sand accretion. We surveyed the biogeography, functional morphology, and associated change in sand elevation of the four dune grass species along a 320-kilometer distance across the Outer Banks. We found that A. breviligulata had dense and clumped shoots, which correlated with the greatest sand accretion. Coupled with fast lateral spread, it tends to build tall and wide foredunes. Uniola paniculata had fewer but taller shoots and was associated with ~42% lower sand accretion. Coupled with slow lateral spread, it tends to build steeper and narrower dunes. Panicum amarum had similar shoot densities and associated sand accretion to U. paniculata despite its shorter shoots, suggesting that shoot density is more important than morphology. Finally, we hypothesize, given the distributions of the grass species, that foredunes may be taller and wider and have better coastal protection properties in the north where A. breviligulata is dominant. If under a warming climate A. breviligulata experiences a range shift to the north, as appears to be occurring with U. paniculata, changes in grass dominance and foredune morphology could make for more vulnerable coastlines.

Highlights

  • Over the last decade, there has been growing recognition that coastal interface habitats such as dunes provide important protection from the threats of extreme storms and chronic sea level rise [1,2].Dunes, and the services they provide, arise from the feedback between vegetation and sediment supply [3,4,5]

  • We suggest that determining the functional role of dune grass species to dune geomorphology at regional scales will require quantitative analyses that partition the relative contributions of sand supply, beach geomorphology, and dune grass species abundance

  • We found that a suite of dune grass species, which overlap in their distributions

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Summary

Introduction

The services they provide, arise from the feedback between vegetation and sediment supply [3,4,5] This feedback process builds dunes, reducing vulnerability to coastal flooding and erosion [6,7], providing habitat for wildlife [8], and serving to sequester carbon [9]. One area of focus has centered on the role of species-specific biophysical feedbacks of dune plants in determining dune geomorphology [4,5,10,11,12,13,14,15,16,17,18,19] These studies show that vegetation functional morphology and its interaction with windblown sand can contribute to the variability in dune geomorphology at local to landscape level scales. A positive feedback between plant growth and accretion occurs, eventually resulting in foredunes that vary in size and shape [5,10,11,12,13,18,19,22,23]

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