Carbon Balance in Salt Marsh and Mangrove Ecosystems: A Global Synthesis

Alongi, Daniel M.

doi:10.3390/jmse8100767

Cited by 128 publications

(95 citation statements)

References 227 publications

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“…According to Figure 5, most carbons were stored in the soil, which accounts for 64% of total carbon stock. This observation is quite close to a previous study that states 77% of total carbon stock in the mangrove ecosystem was stored in soil (Alongi 2020;Kauffman et al 2014;Sasmito et al 2020b). Coastal ecosystem are known to have higher carbon accumulation in sediments/soil compared to terrestrial vegetation mainly because of high autochthonous and allochthonous inputs and low decomposition rates of organic matter due to the mostly anoxic conditions in the sediment (Kristensen 2000;Donato et al 2011;Kida and Fujitake 2020).…”

Section: Soil Properties and Soil Carbon Stocksupporting

confidence: 91%

“…Globally mangrove ecosystem has a total carbon stock of 738 ± 27.9 Mg C ha -1 of which 77% of the carbon is stored in soil (Alongi 2020). Although mangrove forests in the world only account for 0.2% of terrestrial vegetation coverage (Hamilton and Casey 2016), in a country that has extensive mangrove area, it is essential to consider the mangrove ecosystem as a mitigation plan.…”

Section: Introductionmentioning

confidence: 99%

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Environmental conditions to support blue carbon storage in mangrove forest: A case study in the mangrove forest, Nusa Lembongan, Bali, Indonesia

2021

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Abstract. Pricillia CC, Patria MP, Herdiansyah H. 2021. Environmental conditions to support blue carbon storage in mangrove forest: A case study in the mangrove forest, Nusa Lembongan, Bali, Indonesia. Biodiversitas 22: 3304-3314. Mangrove ecosystems can provide ecosystem services to mitigate climate change by absorbing and storing carbon in their systems. The question arises of how to manage a mangrove forest to store more carbon. The Nusa Lembongan mangrove forest was examined to assess the optimal environmental settings for blue carbon storage in the mangrove ecosystem. Five stations were selected purposively. The parameters observed in each station were aboveground living biomass, mangrove stand density, clay percentage in soil, bulk density, water content, soil organic carbon (%C), and soil organic nitrogen (%N). Based on this study, the total carbon stock in mangrove forest Nusa Lembongan was 68.10 ± 20.92 Mg C ha-1 and equals to 249.95 ± 76.77 MgCO2 ha-1 with a significant contribution of soil carbon stock. This study indicates that the essential parameters that can promote carbon sequestration in mangrove forest Nusa Lembongan were aboveground living biomass, soil organic carbon content and soil organic nitrogen content. In addition, as soil organic carbon content also negatively correlates with bulk density, it also can be considered. These findings can contribute to blue carbon planning and management to improve the effectiveness of the blue carbon project.

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Section: Soil Properties and Soil Carbon Stocksupporting

confidence: 91%

Section: Introductionmentioning

confidence: 99%

Environmental conditions to support blue carbon storage in mangrove forest: A case study in the mangrove forest, Nusa Lembongan, Bali, Indonesia

2021

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“…Mangrove PON export accounts for only 1.5% of the entire world's river discharge [249]. The contributions of mangrove N 2 O emissions, denitrification, and burial to the global coastal ocean [250] are modest (0.4%, 0.5-2.0% and 6%, respectively), but are disproportionate relative to their small area (0.31%) [251].…”

Section: An Ecosystem-level View Of Mangrove Forests: a N Budgetmentioning

confidence: 99%

Nitrogen Cycling and Mass Balance in the World’s Mangrove Forests

Alongi

2020

Nitrogen

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Nitrogen (N) cycling in mangroves is complex, with rapid turnover of low dissolved N concentrations, but slow turnover of particulate N. Most N is stored in soils. The largest sources of N are nearly equal amounts of mangrove and benthic microalgal primary production. Dissolved N fluxes between the forests and tidal waters show net uptake, indicating N conservation. N2-fixation is underestimated as rapid rates measured on tree stems, aboveground roots and cyanobacterial mats cannot currently be accounted for at the whole-forest scale due to their extreme patchiness and the inability to extrapolate beyond a localized area. Net immobilization of NH4+ is the largest ecosystem flux, indicating N retention. Denitrification is the largest loss of N, equating to 35% of total N input. Burial equates to about 29% of total inputs and is the second largest loss of N. Total inputs slightly exceed total outputs, currently suggesting net N balance in mangroves. Mangrove PON export equates to ≈95% of PON export from the world’s tropical rivers, but only 1.5% of the entire world’s river discharge. Mangrove N2O emissions, denitrification, and burial contribute 0.4%, 0.5–2.0% and 6%, respectively, to the global coastal ocean, which are disproportionate to their small worldwide area.

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“…Mangroves have one of the highest aerial carbon burial rates due to high primary production and complex root systems that allow organic matter deposition and long-term storage in the anoxic soil layers (Alongi 2020;Jennerjahn 2020). Part of the mangrove soil carbon might be released to the atmosphere after microbial decomposition and exported to ocean as particulate and dissolved matter (Bouillon et al 2008;Volta et al 2020).…”

mentioning

confidence: 99%

Carbon and alkalinity outwelling across the groundwater‐creek‐shelf continuum off Amazonian mangroves

Cabral

Dittmar

Call

et al. 2021

Limnol Oceanogr Letters

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Carbon sequestration in mangroves is often estimated from their sediment storage capacity. However, lateral transport (outwelling) of dissolved carbon and alkalinity from intertidal wetlands can also drive long-term storage in the ocean. Here, we quantified outwelling rates across the groundwater-creek-shelf continuum of the world's largest continuous mangrove belt in the Amazon region. Dissolved inorganic carbon (DIC) fluxes exceeded dissolved organic carbon over all spatial scales. Since 90% AE 13% of mangrove-derived DIC was bicarbonate, there is potential for long-term carbon storage offshore. Outwelling seems to exceed sediment burial as a carbon sequestration pathway in this and other mangrove-dominated coastlines.

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Carbon Balance in Salt Marsh and Mangrove Ecosystems: A Global Synthesis

Cited by 128 publications

References 227 publications

Environmental conditions to support blue carbon storage in mangrove forest: A case study in the mangrove forest, Nusa Lembongan, Bali, Indonesia

Environmental conditions to support blue carbon storage in mangrove forest: A case study in the mangrove forest, Nusa Lembongan, Bali, Indonesia

Nitrogen Cycling and Mass Balance in the World’s Mangrove Forests

Carbon and alkalinity outwelling across the groundwater‐creek‐shelf continuum off Amazonian mangroves

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