Rapid shoreward encroachment of salt marsh cordgrass in response to accelerated sea-level rise

Donnelly, Jeffrey P.; Bertness, Mark D.

doi:10.1073/pnas.251209298

Cited by 312 publications

(228 citation statements)

References 21 publications

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“…Indeed, coastal plants can build coastal landforms through a coupled process of ecological succession and sedimentary accretion (13,22). We conclude that coastal vegetation is best suited to modify and control sedimentary dynamics in response to gradual phenomena like sea-level rise or tidal forces (23,24), but is less well-suited to resist punctuated disturbances (25,26) at the seaward margin of salt marshes, specifically breaking waves. In addition, the soil type (27) and geographical setting (28) are the most important factors to consider when comparing erosion rates among sites.…”

Section: Discussionmentioning

confidence: 94%

Does vegetation prevent wave erosion of salt marsh edges?

Feagin

Lozada-Bernard

Ravens

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

248

154

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This study challenges the paradigm that salt marsh plants prevent lateral wave-induced erosion along wetland edges by binding soil with live roots and clarifies the role of vegetation in protecting the coast. In both laboratory flume studies and controlled field experiments, we show that common salt marsh plants do not significantly mitigate the total amount of erosion along a wetland edge. We found that the soil type is the primary variable that influences the lateral erosion rate and although plants do not directly reduce wetland edge erosion, they may do so indirectly via modification of soil parameters. We conclude that coastal vegetation is bestsuited to modify and control sedimentary dynamics in response to gradual phenomena like sea-level rise or tidal forces, but is less well-suited to resist punctuated disturbances at the seaward margin of salt marshes, specifically breaking waves.coast ͉ hurricane ͉ wave attenuation ͉ wetland

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Section: Discussionmentioning

confidence: 94%

Does vegetation prevent wave erosion of salt marsh edges?

Feagin

Lozada-Bernard

Ravens

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

248

154

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“…The NYC tide-gauge data further support the late 19th century timing of the SLR increase. Linear regression of segments of the NYC tide-gauge data indicate an increase in the rate of SLR from about 1.0 mm/year between 1856 and 1878 to 2.4 mm/year between 1893 and 1921 A.D. [Donnelly and Bertness, 2001]. An increase in the rate of SLR at this time is also supported by the onset of transgressive migration of low-marsh cordgrass (Spartina alterniflora) into the high marsh in the region [Donnelly and Bertness, 2001].…”

Section: Discussionmentioning

confidence: 96%

Coupling instrumental and geological records of sea‐level change: Evidence from southern New England of an increase in the rate of sea‐level rise in the late 19th century

Donnelly

Cleary

Newby

et al. 2004

Geophysical Research Letters

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169

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[1] We construct a high-resolution relative sea-level record for the past 700 years by dating basal salt-marsh peat samples above a glacial erratic in an eastern Connecticut salt marsh, to test whether or not the apparent recent acceleration in the rate of sea-level rise (SLR) is coeval with climate warming. The data reveal an average SLR rate of 1.0 ± 0.2 mm/year from about 1300 to 1850 A.D. Coupling of the regional tide-gauge data (1856 to present) with this marsh-based record indicates that the nearly three-fold increase in the regional rate of SLR to modern levels likely occurred in the later half of the 19th century. Thus the timing of the observed SLR rate increase is coincident with the onset of climate warming, indicating a possible link between historic SLR increases and recent temperature increases. INDEX TERMS: 4556

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“…The model describes the evolution of a marsh transect perpendicular to a tidal channel, which delivers inorganic sediment, by focusing on accretion−submersion processes rather than on marsh lateral erosion or expansion (33,34). Changes in the marsh surface elevation, z, at a position x along the marsh transect are dictated by the sum of the rate of inorganic soil deposition, Q s (x), the rate of sediment trapping by where B a (x) and B b (x) are aboveground and belowground biomass (linear functions of ΔCO 2 ), and R is the RRSLR (Table S3).…”

Section: Significancementioning

confidence: 99%

Spatial response of coastal marshes to increased atmospheric CO ₂

Ratliff

Braswell

Marani

2015

Proc. Natl. Acad. Sci. U.S.A.

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The elevation and extent of coastal marshes are dictated by the interplay between the rate of relative sea-level rise (RRSLR), surface accretion by inorganic sediment deposition, and organic soil production by plants. These accretion processes respond to changes in local and global forcings, such as sediment delivery to the coast, nutrient concentrations, and atmospheric CO 2 , but their relative importance for marsh resilience to increasing RRSLR remains unclear. In particular, marshes up-take atmospheric CO 2 at high rates, thereby playing a major role in the global carbon cycle, but the morphologic expression of increasing atmospheric CO 2 concentration, an imminent aspect of climate change, has not yet been isolated and quantified. Using the available observational literature and a spatially explicit ecomorphodynamic model, we explore marsh responses to increased atmospheric CO 2 , relative to changes in inorganic sediment availability and elevated nitrogen levels. We find that marsh vegetation response to foreseen elevated atmospheric CO 2 is similar in magnitude to the response induced by a varying inorganic sediment concentration, and that it increases the threshold RRSLR initiating marsh submergence by up to 60% in the range of forcings explored. Furthermore, we find that marsh responses are inherently spatially dependent, and cannot be adequately captured through 0-dimensional representations of marsh dynamics. Our results imply that coastal marshes, and the major carbon sink they represent, are significantly more resilient to foreseen climatic changes than previously thought.sea-level rise | coastal marshes | coastal dynamics | atmospheric CO 2 | CO 2 fertilization C oastal marsh extent and morphology are directly controlled by rate of relative sea-level rise (RRSLR) and the soil accretion rate, the latter associated with inorganic sediment deposition and organic soil production by plants. Previous studies observed that CO 2 fertilization increases marsh plant biomass productivity through increased water use efficiency and photosynthesis (1), and hypothesized that, as a consequence, marsh resilience should increase via increased organic accretion (2, 3). However, this hypothesis has not yet been tested, and the observed increased plant productivity in response to the CO 2 fertilization effect has not been translated into its actual geomorphic effects. In fact, direct CO 2 effects on vegetation and marsh accretion (as opposed to its indirect effects, e.g., via the increase in temperature) have not yet been incorporated into marsh models, and their importance relative to other leading forcings of marsh dynamics (e.g., inorganic deposition, RRSLR, nutrient levels) remains unknown. Here we use existing data and a 1D ecomorphodynamic model to assess the direct impacts of elevated CO 2 on marsh morphology, relative to ongoing [e.g., RRSLR, and suspended sediment concentration (SSC)] and emerging [nutrient levels (4-6)] environmental change. Vegetation Responses to Changing Environmental ConditionsWe use publ...

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Rapid shoreward encroachment of salt marsh cordgrass in response to accelerated sea-level rise

Cited by 312 publications

References 21 publications

Does vegetation prevent wave erosion of salt marsh edges?

Does vegetation prevent wave erosion of salt marsh edges?

Coupling instrumental and geological records of sea‐level change: Evidence from southern New England of an increase in the rate of sea‐level rise in the late 19th century

Spatial response of coastal marshes to increased atmospheric CO ₂

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Rapid shoreward encroachment of salt marsh cordgrass in response to accelerated sea-level rise

Cited by 312 publications

References 21 publications

Does vegetation prevent wave erosion of salt marsh edges?

Does vegetation prevent wave erosion of salt marsh edges?

Coupling instrumental and geological records of sea‐level change: Evidence from southern New England of an increase in the rate of sea‐level rise in the late 19th century

Spatial response of coastal marshes to increased atmospheric CO 2

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Spatial response of coastal marshes to increased atmospheric CO ₂