Vulnerability of Louisiana’s coastal wetlands to present-day rates of relative sea-level rise

Jankowski, K. L.; Törnqvist, Torbjörn E.; Fernandes, Anjali M.

doi:10.1038/ncomms14792

Cited by 243 publications

(244 citation statements)

References 40 publications

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“…Rogers et al (2019) recently suggested that an increase in vertical accommodation space driven by RSLR may lead to increasing sedimentation and C sequestration; however, the limited tidal exchange and reduced sediment availability in this region may contradict this trend. Mean observed RSLR in this area is 9.5 mm/yr (AE6.33 mm/yr, n = 89; Jankowski et al 2017), which is 1.5 times higher than even the highest longer-term accretion rate we measured in this study, suggesting both created and natural marshes are at risk of drowning in SNWR. Our results support and augment these findings by demonstrating a substantial accretion deficit in created marshes in the western Chenier Plain, irrespective of environmental conditions or age.…”

Section: Created Marsh Persistencecontrasting

confidence: 52%

“…Aboveground litter from these species may therefore remain in the substrate for longer periods than S. alterniflora litter, which is readily decomposed (Lonard et al 2010(Lonard et al , 2013). Within the 13-and 32-yr-old marshes, however, stem density remained the most important predictor of LCAR, suggesting these marshes remain dependent upon autochthonous, rather than allochthonous contributions to sustain soil C accumulation rates (Jankowski et al 2017). That is, it floods at a depth and frequency that suppresses vegetative growth and decreases overall vertical accretion and organic C accumulation rates, which were 3.7 and 5.7 times lower than rates found in the 13-yr-old marsh.…”

Section: Role Of Vegetation and Environmental Factors In Accretion Anmentioning

confidence: 98%

“…Due to tight coupling between marsh hydrology, vegetation type and productivity, and deposition rates (Morris et al 2002, Stagg and Mendelssohn 2010, Kirwan and Megonigal 2013, Snedden and Steyer 2013, teasing apart direct and indirect drivers of CAR can be challenging. Recently, researchers have shown that vertical accretion rates in the western Chenier Plain are an average of two times lower than in the Mississippi Delta, which may be due to shallow subsidence, distance from a fluvial sediment source, and the effects of Chenier ridges and impoundments (Jankowski et al 2017). Many subsiding coastal marshes in Louisiana are subject to low allochthonous sediment availability and are therefore reliant upon autochthonous organic inputs to maintain marsh elevation in the face of high rates of relative sea-level rise (RSLR; Turner and Streever 2002, DeLaune and Pezeshki 2002, Lane et al 2016.…”

Section: Introductionmentioning

confidence: 99%

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Factors influencing blue carbon accumulation across a 32‐year chronosequence of created coastal marshes

2019

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Saline coastal marshes are blue carbon ecosystems with relatively high soil carbon (C) stocks and high rates of soil C accumulation. Loss of saline wetlands due to relative sea-level rise, land-use change, and hydrologic alterations liberates previously stored C and reduces the capacity for future C sequestration. Widespread wetland loss has prompted marsh restoration and creation projects around the world; however, little is known about the timescale and capacity for created marshes to function as blue C sinks and the role of environmental conditions in mediating soil C accumulation in restoration sites. Using a chronosequence of five created saline marshes ranging in age from 5 to 32 yr and two adjacent natural reference marshes in southwest Louisiana, USA, short-and longer-term C accumulation rates (SCAR and LCAR, respectively) were determined using feldspar marker horizons and peat depth in cores at six locations in each marsh. Created marshes ranged in elevation from À12 to 41 cm (NAVD88) and supported assorted plant community compositions driven by local environmental conditions. SCAR ranged from 75 to 430 g CÁm À2 Áyr À1 , which were comparable in the two youngest and two oldest marshes. Longer-term CAR ranged from 18 to 99 g CÁm À2 Áyr À1 but did not significantly differ among marshes of different ages.Our findings indicate that LCAR in these created marshes were influenced by site-specific environmental conditions (i.e., stem density and mineral sediment) rather than marsh age. Results suggest that conditions appropriate for the establishment of vegetation with high stem densities, such as Distichlis spicata and Spartina patens, may facilitate higher LCAR in created marshes, which may be useful for restoration project planning and mitigation of climate change.

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Section: Created Marsh Persistencecontrasting

confidence: 52%

Section: Role Of Vegetation and Environmental Factors In Accretion Anmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

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Factors influencing blue carbon accumulation across a 32‐year chronosequence of created coastal marshes

2019

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“…Our results highlight the utility of the more plentiful mud load. While significant land loss in the Mississippi Delta is inevitable, accretion rates that persisted in the mud-dominated ACS for centuries (1-4 cm yr −1 ; Shen et al, 2015) may locally be sufficient to keep up with present-day rates of relative sea-level rise in the MD (1.3 ± 0.9 cm yr −1 ) (Jankowski et al, 2017) even after accounting for enhanced compaction due to sediment loading (Törnqvist et al, 2008). The goal of river diversions is to maximize their land building potential, which is determined by both sediment supply and SRE.…”

Section: Implications For Delta Evolution and Sustainabilitymentioning

confidence: 99%

Efficient retention of mud drives land building on the Mississippi Delta plain

Esposito

Shen

Törnqvist³

et al. 2017

Earth Surf. Dynam.

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Abstract. Many of the world's deltas -home to major population centers -are rapidly degrading due to reduced sediment supply, making these systems less resilient to increasing rates of relative sea-level rise. The Mississippi Delta faces some of the highest rates of wetland loss in the world. As a result, multibillion dollar plans for coastal restoration by means of river diversions are currently nearing implementation. River diversions aim to bring sediment back to the presently sediment-starved delta plain. Within this context, sediment retention efficiency (SRE) is a critical parameter because it dictates the effectiveness of river diversions. Several recent studies have focused on land building along the open coast, showing SREs ranging from 5 to 30 %. Here we measure the SRE of a large relict crevasse splay in an inland, vegetated setting that serves as an appropriate model for river diversions. By comparing the mass fraction of sand in the splay deposit to the estimated sand fraction that entered it during its life cycle, we find that this mud-dominated sediment body has an SRE of ≥ 75 %, i.e., dramatically higher than its counterparts on the open coast. Our results show that transport pathways for mud are critical for delta evolution and that SRE is highly variable across a delta. We conclude that sediment diversions located in settings that are currently still vegetated are likely to be the most effective in mitigating land loss and providing long-term sustainability.

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“…On contrary, increased air temperature and CO 2 concentration can contribute to the marsh stability against sea-level rise. The fertilization effects of the increased air temperature and atmospheric CO 2 allow the coastal marshes to be more resilient against sea-level rise, but this study documents a sig- (Jankowski et al, 2017), the relative relationship between sediment supply and sea-level rise of different locations (Mariotti & Fagherazzi, 2010), and the availability of accommodation space (Schuerch et al, 2018) may provide more insights the spatial patterns of the area changes. Although the enhancement of plant growth from CO 2 , as discussed earlier, is mainly for C3 plants, the fertilization of CO 2 , based on a modeling study, can increase the marsh elevation for a mixed C3 and C4 plant community (by increasing plant production) in similar magnitude to the effect of increasing inorganic sediment input (Ratliff et al, 2015).…”

Section: The Marsh Area Changes In the Last 30 Yearsmentioning

confidence: 65%

Feedback of coastal marshes to climate change: Long‐term phenological shifts

Kearney

Turner

2019

Ecology and Evolution

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Coastal marshes are important carbon sinks facing serious threats from climatic stressors. Current research reveals that the growth of individual marsh plants is susceptible to a changing climate, but the responses of different marsh systems at a landscape scale are less clear. Here, we document the multi‐decadal changes in the phenology and the area of the extensive coastal marshes in Louisiana, USA, a representative of coastal ecosystems around the world that currently experiencing sea‐level rise, temperature warming, and atmospheric CO2 increase. The phenological records are constructed using the longest continuous satellite‐based record of the Earth's ecosystems, the Landsat data, and an advanced modeling technique, the nonlinear mixed model. We find that the length of the growing seasons of the intermediate and brackish marshes increased concomitantly with the atmospheric CO2 concentration over the last 30 years, and predict that such changes will continue and accelerate in the future. These phenological changes suggest a potential increase in CO2 uptake and thus a negative feedback mechanism to climate change. The areas of the freshwater and intermediate marshes were stable over the period studied, but the areas of the brackish and saline marshes decreased substantially, suggesting ecosystem instability and carbon storage loss under the anticipated sea‐level rise. The marshes' phenological shifts portend their potentially critical role in climate mitigation, and the different responses among systems shed light on the underlying mechanisms of such changes.

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Vulnerability of Louisiana’s coastal wetlands to present-day rates of relative sea-level rise

Cited by 243 publications

References 40 publications

Factors influencing blue carbon accumulation across a 32‐year chronosequence of created coastal marshes

Factors influencing blue carbon accumulation across a 32‐year chronosequence of created coastal marshes

Efficient retention of mud drives land building on the Mississippi Delta plain

Feedback of coastal marshes to climate change: Long‐term phenological shifts

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