Warming accelerates mangrove expansion and surface elevation gain in a subtropical wetland

Coldren, Glenn; Langley, J. Adam; Feller, Ilka C.; Chapman, Samantha K.

doi:10.1111/1365-2745.13049

Cited by 60 publications

(48 citation statements)

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“…In order to maintain equilibrium with sea level (Nyman et al 2006, McKee et al 2007, Kirwan et al 2016, Morris et al 2016), many coastal wetlands must increase vertical soil elevation largely through belowground storage of OC (Breithaupt et al 2017). Studies comparing adjacent marsh and mangrove systems are divided on whether mangrove ecosystems support larger (Comeaux et al 2012, Bianchi et al 2013, Yando et al 2016, Coldren et al 2018 or similar (Perry and Mendelssohn 2009, Henry and Twilley 2013, Doughty et al 2016, McKee and Vervaeke 2017) OC stocks and storage rates compared to marshes. Studies comparing adjacent marsh and mangrove systems are divided on whether mangrove ecosystems support larger (Comeaux et al 2012, Bianchi et al 2013, Yando et al 2016, Coldren et al 2018 or similar (Perry and Mendelssohn 2009, Henry and Twilley 2013, Doughty et al 2016, McKee and Vervaeke 2017) OC stocks and storage rates compared to marshes.…”

Section: Discussionmentioning

confidence: 99%

“…A crucial unknown variable is how shifting dominant species identity and cover following mangrove expansion or mortality may alter OC storage. Studies comparing adjacent marsh and mangrove systems are divided on whether mangrove ecosystems support larger (Comeaux et al 2012, Bianchi et al 2013, Yando et al 2016, Coldren et al 2018 or similar (Perry and Mendelssohn 2009, Henry and Twilley 2013, Doughty et al 2016, McKee and Vervaeke 2017) OC stocks and storage rates compared to marshes. Furthermore, studying adjacent marsh and mangrove-dominated areas risks confounding the impacts of the vegetation itself with the abiotic conditions driving vegetation zonation.…”

Section: Discussionmentioning

confidence: 99%

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Quantifying how changing mangrove cover affects ecosystem carbon storage in coastal wetlands

Charles

Kominoski

Armitage

et al. 2019

Ecology

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2020.Quantifying how changing mangrove cover affects ecosystem carbon storage in coastal wetlands. Ecology 101(2):Abstract. Despite overall global declines, mangroves are expanding into and within many subtropical wetlands, leading to heterogeneous cover of marsh-mangrove coastal vegetation communities near the poleward edge of mangroves' ranges. Coastal wetlands are globally important carbon sinks, yet the effects of shifts in mangrove cover on organic-carbon (OC) storage remains uncertain. We experimentally maintained black mangrove (Avicennia germinans) or marsh vegetation in patches (n = 1,120, 3 9 3 m) along a gradient in mangrove cover (0-100%) within coastal wetland plots (n = 10, 24 9 42 m) and measured changes in OC stocks and fluxes. Within patches, above and belowground biomass (OC) was 1,630% and 61% greater for mangroves than for recolonized marshes, and soil OC was 30% greater beneath mangrove than marsh vegetation. At the plot scale, above and belowground biomass increased linearly with mangrove cover but soil OC was highly variable and unrelated to mangrove cover. Root ingrowth was not different in mangrove or marsh patches, nor did it change with mangrove cover. After 11 months, surface OC accretion was negatively related to plot-scale mangrove cover following a high-wrack deposition period. However, after 22 months, accretion was 54% higher in mangrove patches, and there was no relationship to plot-scale mangrove cover. Marsh (Batis maritima) leaf and root litter had 1,000% and 35% faster breakdown rates (k) than mangrove (A. germinans) leaf and root litter. Soil temperatures beneath mangroves were 1.4°C lower, decreasing aboveground k of fast-(cellulose) and slow-decomposing (wood) standard substrates. Wood k in shallow soil (0-15 cm) was higher in mangrove than marsh patches, but vegetation identity did not impact k in deeper soil (15-30 cm). We found that mangrove cover enhanced OC storage by increasing biomass, creating more recalcitrant organic matter and reducing k on the soil surface by altering microclimate, despite increasing wood k belowground and decreasing allochthonous OC subsidies. Our results illustrate the importance of mangroves in maintaining coastal OC storage, but also indicate that the impacts of vegetation change on OC storage may vary based on ecosystem conditions, organic-matter sources, and the relative spatiotemporal scales of mangrove vegetation change.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Quantifying how changing mangrove cover affects ecosystem carbon storage in coastal wetlands

Charles

Kominoski

Armitage

et al. 2019

Ecology

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“…Freeze‐tolerant salt marshes dominate areas that are too cold for mangrove forests, while mangroves dominate coastal reaches with mild winters. Hence, coastal wetlands in this region contain a dynamic mosaic of mangrove forest and salt marsh plants (Coldren, Langley, Feller, & Chapman, ; Langston, Kaplan, & Angelini, ; Macy et al, ; Perry & Mendelssohn, ; Weaver & Armitage, ).…”

Section: Methodsmentioning

confidence: 99%

Temperature thresholds for black mangrove (Avicennia germinans) freeze damage, mortality and recovery in North America: Refining tipping points for range expansion in a warming climate

et al. 2019

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Near the tropical‐temperate transition zone, warming winter temperatures are expected to facilitate the poleward range expansion of freeze‐sensitive tropical organisms. In coastal wetlands of eastern and central North America, freeze‐sensitive woody plants (mangroves) are expected to expand northward into regions currently dominated by freeze‐tolerant herbaceous salt marsh plants. To advance understanding of mangrove range expansion, there is a need to refine temperature thresholds for mangrove freeze damage, mortality and recovery. We integrated data from 38 sites spread across the mangrove range edge in the Gulf of Mexico and Atlantic coasts of North America, including data from a regional collaborative network – the Mangrove Migration Network. In 2018, an extreme freeze event affected 60% of these sites, with minimum temperatures ranging from 0 to −7°C. We used temperature and vegetation data from before and after the freeze to quantify temperature thresholds for leaf damage, mortality and biomass recovery of the black mangrove (Avicennia germinans) – the most freeze‐tolerant mangrove species in North America. For A. germinans individuals near their northern range limit, our results indicate that temperature thresholds for leaf damage are close to −4°C, but temperature thresholds for mortality are closer to −7°C. Thresholds are expected to be warmer for more southern A. germinans individuals and for the other two common mangrove species in the region (Laguncularia racemosa and Rhizophora mangle). Regenerative buds allowed A. germinans to resprout and recover quickly from above‐ground freeze damage. Hence, biomass recovery levels during the first post‐freeze growing season were 90%, 78%, 62% and 45% for temperatures of −4, −5, −6 and −7°C, respectively. Due to a combination of vigorous resprouting and new recruitment from propagules, we expect full recovery at most sites within 1–3 years, assuming no further freeze events. Synthesis. To improve predictions of tropical range expansion in response to climate change, there is a need to better understand tropical species’ responses to winter temperature extremes. Collectively, our results refine temperature thresholds for A. germinans freeze damage, mortality and recovery, which can improve predictions of mangrove range expansion and coastal wetland ecological transformations in a warming climate.

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“…Another visibly prominent shift in coastal ecology is the poleward migration of mangroves due to declining freeze frequencies and landward migration due to seawater intrusion 84 . Conversion from herbaceous-dominated to woody plantdominated wetlands greatly increases aboveground carbon uptake on the landscape scale 52,85 and can accelerate soil elevation gain 86 and long-term wood retention in channels and floodplain microtopography 85 , influencing long-term persistence of these ecosystems. Conversely, seawater intrusion into freshwater wetlands at the upstream edge of the coastal interface can cause vegetation death and accelerated soil carbon loss resulting in the collapse of the ground surface and a conversion of the plantdominated wetland to open brackish water 87 .…”

Section: Challenges For Constraining Coastal Dynamicsmentioning

confidence: 99%

Representing the function and sensitivity of coastal interfaces in Earth system models

et al. 2020

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Between the land and ocean, diverse coastal ecosystems transform, store, and transport material. Across these interfaces, the dynamic exchange of energy and matter is driven by hydrological and hydrodynamic processes such as river and groundwater discharge, tides, waves, and storms. These dynamics regulate ecosystem functions and Earth's climate, yet global models lack representation of coastal processes and related feedbacks, impeding their predictions of coastal and global responses to change. Here, we assess existing coastal monitoring networks and regional models, existing challenges in these efforts, and recommend a path towards development of global models that more robustly reflect the coastal interface. T he coastal interface, where the land and ocean realms meet (e.g., estuaries, tidal wetlands, tidal rivers, continental shelves, and shorelines), is home to some of the most biologically and geochemically active and diverse systems on Earth 1. Although this interface only represents a small fraction of the Earth's surface, it supports a large suite of ecosystem services,

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Warming accelerates mangrove expansion and surface elevation gain in a subtropical wetland

Cited by 60 publications

References 58 publications

Quantifying how changing mangrove cover affects ecosystem carbon storage in coastal wetlands

Quantifying how changing mangrove cover affects ecosystem carbon storage in coastal wetlands

Temperature thresholds for black mangrove (Avicennia germinans) freeze damage, mortality and recovery in North America: Refining tipping points for range expansion in a warming climate

Representing the function and sensitivity of coastal interfaces in Earth system models

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