Spartina alterniflora Biomass Allocation and Temperature: Implications for Salt Marsh Persistence with Sea-Level Rise |
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Authors: | Sarah C. Crosby Angus Angermeyer Jennifer M. Adler Mark D. Bertness Linda A. Deegan Nathaniel Sibinga Heather M. Leslie |
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Affiliation: | 1.Ecology and Evolutionary Biology,Brown University,Providence,USA;2.Marine Biological Laboratory, Ecosystems Center,Woods Hole,USA;3.Harbor Watch, Earthplace, Inc.,Westport,USA;4.Marine Biological Laboratory, Bay Paul Center,Woods Hole,USA;5.School of Natural Resources and Environment,University of Florida,Gainesville,USA;6.Department of Biology,Brooklyn College,Brooklyn,USA;7.Aquatic Research and Environmental Assessment Center,Brooklyn,USA;8.Darling Marine Center,The University of Maine,Walpole,USA |
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Abstract: | To predict the impacts of climate change, a better understanding is needed of the foundation species that build and maintain biogenic ecosystems. Spartina alterniflora Loisel (smooth cordgrass) is the dominant salt marsh-building plant along the US Atlantic coast. It maintains salt marsh elevation relative to sea level by the accumulation of aboveground biomass, which promotes sediment deposition and belowground biomass, which accretes as peat. Peat accumulation is particularly important in elevation maintenance at high latitudes where sediment supply tends to be limited. Latitudinal variation in S. alterniflora growth was quantified in eight salt marshes from Massachusetts to South Carolina. The hypothesis that allocation to aboveground and belowground biomass is phenotypically plastic was tested with transplant experiments among a subset of salt marshes along this gradient. Reciprocal transplants revealed that northern S. alterniflora decreased allocation to belowground biomass when grown in the south. Some northern plants also died when moved south, suggesting that northern S. alterniflora may be stressed by future warming. Southern plants that were moved north showed phenotypic plasticity in biomass allocation, but no mortality. Belowground biomass also decomposed more quickly in southern marshes. Our results suggest that warming will lead northern S. alterniflora to decrease belowground allocation and that belowground biomass will decompose more quickly, thus decreasing peat accumulation. Gradual temperature increases may allow for adaptation and acclimation, but our results suggest that warming will lower the ability of salt marshes to withstand sea-level rise. |
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