Tipping points of Mississippi Delta marshes due to accelerated sea-level rise

Törnqvist, Torbjörn E.; Jankowski, K. L.; Li, Yong-Xiang; González, Juan Luis Jiménez

doi:10.1126/sciadv.aaz5512

Cited by 93 publications

(83 citation statements)

References 43 publications

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“…A recent global‐scale prediction of coastal wetland extent for the remainder of this century (Schuerch et al., 2018) has suggested that even under pessimistic climate scenarios, and provided that there is room for landward migration, coastal wetland area will generally increase, echoing previous model studies that have suggested that coastal marshes can keep up with rates of sea‐level rise as high as 10–50 mm yr −1 (Kirwan et al., 2016). These results stand in stark contrast with studies based on the geologic record that show tipping points for marsh drowning in the Mississippi Delta (USA) at rates of relative sea‐level rise (RSLR) of ∼3 mm yr −1 (Törnqvist et al., 2020) and an inability of mangroves worldwide to initiate sustained accretion when rates of RSLR exceed ∼6 mm yr −1 (Saintilan et al., 2020). The main purpose of this Commentary is to examine these seemingly contradictory outcomes.…”

Section: Introductioncontrasting

confidence: 78%

“…A striking illustration is provided by the stratigraphic record from the Mississippi Delta where during the early Holocene, when rates of RSLR approached 10 mm yr −1 , incipient (or fringing) marshes only a few kilometers wide rapidly migrated landward with rising sea level. This resulted in thin marsh strata (typically a few decimeters or less) that quickly drowned and were overlain by open-water (lagoonal) deposits (Törnqvist et al, 2020). Only when RSLR decelerated to rates <3 mm yr −1 ∼7,000 years ago, the Mississippi Delta as we know it today started to form by means of rapid shoreline progradation (on the order of 100-150 m yr −1 ; Chamberlain et al [2018]) and associated marsh expansion, echoing delta initiation on a global scale around this time (Stanley & Warne, 1994).…”

Section: The Importance Of Timescalementioning

confidence: 99%

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Coastal Wetland Resilience, Accelerated Sea‐Level Rise, and the Importance of Timescale

et al. 2021

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Coastal wetlands (marshes and mangroves) are among the most valuable ecosystems on the planet (Barbier, 2019; Costanza et al., 2014), yet they are threatened by accelerated sea-level rise and other human impacts. Coastal wetlands occupy extensive portions of low-elevation coastal zones (LECZs; commonly defined as <10 m above mean sea level) that are home to all or portions of 21 of the 33 largest megacities (population >10 million) worldwide (https://digitallibrary.un.org/record/3799524). Recent work has shown that LECZs are considerably lower in elevation than previously assumed (Kulp & Strauss, 2019) and several LECZs may subside more rapidly than commonly thought (Keogh & Törnqvist, 2019). Given that the acceleration of global sea-level rise will continue well into the future (Oppenheimer et al., 2019), predicting the extent and health of coastal wetlands is a topic of great import. A recent global-scale prediction of coastal wetland extent for the remainder of this century (Schuerch et al., 2018) has suggested that even under pessimistic climate scenarios, and provided that there is room for landward migration, coastal wetland area will generally increase, echoing previous model studies that have suggested that coastal marshes can keep up with rates of sea-level rise as high as 10-50 mm yr −1 (Kirwan et al., 2016). These results stand in stark contrast with studies based on the geologic record that show tipping points for marsh drowning in the Mississippi Delta (USA) at rates of relative sea-level rise (RSLR) of ∼3 mm yr −1 (Törnqvist et al., 2020) and an inability of mangroves worldwide to initiate sustained accretion when rates of RSLR exceed ∼6 mm yr −1 (Saintilan et al., 2020). The main purpose of this Commentary is to examine these seemingly contradictory outcomes. We first discuss the concept of accommodation that plays an increasingly important role in models that seek to predict coastal wetland change until the end of this century (e.g., Schuerch et al., 2018). We then make the case that these models must be constrained by the stratigraphic record (i.e., observations over centennial to millennial timescales) and we discuss key reasons why instrumental observations (i.e., annual to decadal timescales) cannot fully capture the outcome Abstract Recent studies have produced conflicting results as to whether coastal wetlands can keep up with present-day and future sea-level rise. The stratigraphic record shows that threshold rates for coastal wetland submergence or retreat are lower than what instrumental records suggest, with wetland extent that shrinks considerably under high rates of sea-level rise. These apparent conflicts can be reconciled by recognizing that many coastal wetlands still possess sufficient elevation capital to cope with sea-level rise, and that processes like sediment compaction, ponding, and wave erosion require multidecadal or longer timescales to drive wetland loss that is in many cases inevitable. Plain Language Summary The rapid, climate-driven acceleration of global sea level thr...

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Section: Introductioncontrasting

confidence: 78%

Section: The Importance Of Timescalementioning

confidence: 99%

Coastal Wetland Resilience, Accelerated Sea‐Level Rise, and the Importance of Timescale

et al. 2021

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“…Though difficult to quantify, the societal benefits (i.e., ecosystem services) provided by coastal ecosystems in Louisiana's Mississippi River Delta have been valued to be at least $12–$47 billion (US dollars) per year (Batker et al, 2010). However, the rate of wetland loss in Louisiana has been very high in the past century, due to a combination of natural and human factors that have reduced the ability of wetlands to build elevation to keep pace with high rates of subsidence and relative sea‐level rise (Blum & Roberts, 2009; Day et al., 2007; Törnqvist, Jankowski, Li, & González, 2020). Between 1932 and 2016, Louisiana lost approximately 4,833 km 2 of wetlands (Couvillion, Beck, Schoolmaster, & Fischer, 2017), and the state has become a prominent global example of the negative linkages between high relative sea‐level rise, sediment delivery alterations and coastal wetland loss (Jankowski, Törnqvist, & Fernandes, 2017; Twilley et al., 2016).…”

Section: Methodsmentioning

confidence: 99%

Frequency of extreme freeze events controls the distribution and structure of black mangroves (Avicennia germinans) near their northern range limit in coastal Louisiana

Osland

Day

Michot

2020

Diversity and Distributions

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Aim Climate change is expected to result in the tropicalization of coastal wetlands in the northern Gulf of Mexico, as warming winters allow tropical mangrove forests to expand their distribution poleward at the expense of temperate salt marshes. Data limitations near mangrove range limits have hindered understanding of the effects of winter temperature extremes on mangrove distribution and structure. Here, we investigated the influence of extreme freeze events on the abundance, height and coverage of black mangroves (Avicennia germinans) near their northern range limit in Louisiana. Location Coastal Louisiana, USA. Methods We quantified the relationships between the frequency of extreme freeze events and A. germinans abundance, height and coverage using: (a) mangrove observation points recorded via aerial surveys from a fixed‐wing aircraft; (b) 30 years of temperature data; and (c) mangrove mortality and leaf damage temperature thresholds. We used freeze frequency data and mangrove–climate relationships to evaluate and spatially depict the risk of A. germinans freeze damage across Louisiana. Results We identified strong negative relationships between the frequency of extreme freeze events and A. germinans abundance, height and coverage. Avicennia germinans is most abundant, tall and continuous along the south‐eastern outer coast of Louisiana, where the frequency of extreme freeze events is reduced (i.e., lower risk of mangrove freeze damage) by the buffering effects of comparatively warm Gulf of Mexico waters. Conversely, the risk of A. germinans freeze damage has historically been very high across Louisiana's Chenier Plain and within more inland wetlands in the Deltaic Plain. Main conclusions Our analyses advance understanding of how the frequency of extreme freeze events controls the distribution, height and coverage of A. germinans near its northern range limit. In addition to informing climate‐smart coastal restoration efforts, our findings can be used to better anticipate and prepare for the tropicalization of temperate wetlands due to climate change.

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“…Tidal marshes provide many well‐documented ecosystem services, including habitat or forage for important fisheries (Boesch & Turner, 1984; Kneib, 1997; Minello et al, 2012), filtering and detoxifying terrestrial runoff (Brin et al, 2010; Nelson & Zavaleta, 2012), and buffering coasts from wave energy and storms (Cochard et al, 2008; Gedan et al, 2011; Knutson et al, 1982). At the same time, tidal marshes face several threats, most notably from accelerating sea level rise (Crosby et al, 2016; Törnqvist et al, 2020), reductions in sediment supply (FitzGerald & Hughes, 2019), impediments to landward migration (Schuerch et al, 2018; Spencer et al, 2016; Thorne et al, 2018), and land reclamation (Ewers Lewis et al, 2019; Gu et al, 2018). Marsh peats found well below present‐day sea level in offshore settings provide examples of marshes that did not keep pace with prehistoric sea level rise (Emery et al, 1965; Wolters et al, 2010).…”

Section: Introductionmentioning

confidence: 99%