Accounting for black carbon lowers estimates of blue carbon storage services

Chew, Swee Theng; Gallagher, John Barry

doi:10.1038/s41598-018-20644-2

Cited by 45 publications

(74 citation statements)

References 39 publications

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“…Clearly, the 382 remaining half of the organic carbon, a seemingly recalcitrant fraction, is more than can be 383 accounted for by the <10% contribution of the BC alone. It is also unlikely in this case that 384 any presence of phytolith occluded carbon was responsible given that the BC methodology 385 may have inadvertently included this form (Chew and Gallagher 2018). What remains is 386 up to speculation; it may consist of bacterial necromass (Burdige 2007 times of over 1000 years (Gewert et al 2015), their amounts as carbon within soils and sediments remain largely unknown.…”

Section: Discussion 372mentioning

confidence: 97%

“…Malaysia) and within the penumbra of the near-annual southwest Borneo and Sumatra 110 haze events. These events ostensibly deposit BC into the estuary from peat fires on the 111 southern part of the island as well as from slash-and-burn land-clearing activities (Gaveau 112 et al 2014;Chew and Gallagher 2018). The two bays are both turbid and shallow (1-3 m) 113 and surrounded by mangrove forests with exposed intertidal mud banks.…”

Section: Study Site 106mentioning

confidence: 99%

“…Pyrogenic carbon is produced by incomplete combustion of 62 biomass and fossil fuels. It is considered sufficiently stable to be outside the climatic carbon loop (Liang et al 2008; Wang et al 2016), and thus its storage and sequestration 64 within seagrass ecosystem sediments cannot be counted as a greenhouse gas mitigation 65 service (Chew and Gallagher 2018). Mass accumulation rates, the product of 66 sedimentation rates and particulate organic carbon (POC) concentrations, have no assumed 67 significant losses after one to two years within their surface sediments (Cebrian 1999).…”

mentioning

confidence: 99%

“…The remaining sediment plug 183 was then dried at 105 °C and the amount of water and sediment was noted to calculate the 184 amount remaining in the mason jars for CO 2 accumulation as dry weight of sediment after 185 correcting for salinity(Lavelle et al 1985). Particulate organic matter (POM), PIC and 186 black organic matter (BOM) from the dried sediment slug was measured gravimetrically 187 by loss on ignition (LOI 0.45g ) in a laboratory furnace (Carbolite CWF 1.8 L;Heiri et al 188 2001;Chew and Gallagher 2018). Additional inter-batch corrections resulting from 189 possible furnace aging and procedural handling differences were performed using in-house 190 local sediment standards taken from the middle of the cores (n = 5) and randomly placed 191 within the furnace.…”

mentioning

confidence: 99%

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Blue carbon sequestration dynamics within tropical seagrass sediments: Long-term incubations for changes over climatic scales

Chuan

Gallagher

Chew

et al. 2019

Preprint

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Determination of blue carbon sequestration in seagrass sediments over 15 climatic time scales relies on several assumptions, such as no loss of particulate organic 16 carbon (POC) after one or two years, tight coupling between POC loss and CO 2 emissions, 17 no dissolution of carbonates and removal of the stable black carbon (BC) contribution. We 18 tested these assumptions via 500-day anoxic decomposition/mineralisation experiments to 19 capture centennial parameter decay dynamics from two sediment horizons robustly dated 20 as 2 and 18 years old. No loss of BC was detected, and decay of POC was best described 21 for both horizons by near-identical reactivity continuum models. The models predicted 22Additional keywords: sediment geochemistry, diagenesis, carbonate, pyrogenic carbon, 31 methane, sediment isotope tomography 32 Introduction 33Seagrasses, along with mangroves, saltmarsh and seaweeds, are increasingly touted 34 as a significant global carbon sink (McLeod et al. 2011). For seagrass in particular, this 35 service is based on two separate concepts: sedimentary carbon stocks and rates of 36 sedimentary carbon sequestration. The stock or storage service concept, in the mitigation 37 of greenhouse gas emissions, is a scalar concept and conceived at the meadow scale. It has 38 traditionally been estimated by potential carbon loss to mineralisation should it be 39 disturbed over a climatic unit of time (Pendleton et al. 2012). The depth of such 40 disturbance, and the extent of its effect on the carbon stock, is dependent on the type of 41 disturbance (Siikamäki et al. 2013;Gallagher 2017) and independent of the time it took the 42 carbon to accumulate. The sediment found within seagrass beds contains a sizable organic 43 component consisting of a mix of seagrass litter, associated epiphyte and microalgal 44 detritus, and additional inputs from adjacent land activities and fluvial deposition as well 45 as saltmarsh and mangrove ecosystems (Kennedy et al. 2010). In contrast, the carbon 46 sequestration service is a vector concept. Rates of sequestration depend on the balance 47

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Section: Discussion 372mentioning

confidence: 97%

Section: Study Site 106mentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

See 2 more Smart Citations

Blue carbon sequestration dynamics within tropical seagrass sediments: Long-term incubations for changes over climatic scales

Chuan

Gallagher

Chew

et al. 2019

Preprint

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“…While measurements of carbon within biomass and sediments can be relatively straightforward, questions have been raised on how stock preservation is assessed as a mitigating service in further release of the dominant greenhouse CO 2 from the marine environment. That is, questions of the extent of loss after disturbance, how much is remineralised over climatic scales, whether to include the presence sedimentary allochthonous organic recalcitrants and particulate inorganic carbon (PIC) as an arbiter of carbon stock mitigation services (Chew and Gallagher 2018; Gallagher 2017). For woody biomass, in particular, how much is released as CO 2 could vary with its use, should it be disturbed or harvested (Eong, 1993).…”

Section: Introductionmentioning

confidence: 99%

Valuing Carbon Stocks across a Tropical Lagoon after Accounting for Black and Inorganic Carbon: Bulk Density Proxies for monitoring

Gallagher

Chew

Madin

et al. 2019

Preprint

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3Managing seagrass and mangrove can be enhanced through carbon valued payment 1 4 incentives schemes. Success will depend on the accuracy and extent of the carbon stock 1 5 mitigation and accessible methods of monitoring and marking changes. In a relatively 1 6 closed socioecological Southeast Asian lagoon we estimated the value of total organic 1 7 carbon stocks (TOC) of both seagrass and mangroves. Mitigation corrections were also 1 8 made for black carbon (BC) and calcareous inorganic carbon equivalents (PIC equiv ), and 1 9 their sediment dry bulk density (DBD) tested as a cost effective means of both estimating 2 0 those stock concepts and possible impacts outside their parameter confidence intervals. 2 1 Overall, seagrass and mangroves TOC densities across the lower lagoon ranged from 2 2 15.3±4.3 and 124.3±21.1 Mg C ha -1 respectively, 175.2±46.9 and 103.2±19.0 Mg C ha -1 2 3 for seagrass and 355.0±24.8 and 350.3±35.2 Mg C ha -1 ) for mangroves across the two 2 4 upper lagoon branches. Only mangrove biomass made significant additional 2 5 contributions ranging from 178.5±62.3 to 120.7±94.8 Mg C ha -1 for lower and upper 2 6 regions respectively. The difference between the lagoons total seagrass and mangroves 2 7 TOC stocks (5.98±0.69 and 390±33.22 GgC respectively) was further amplified by the 2 8 lagoons' larger mangrove area. When corrected for BC and PIC equiv , the carbon stock 2 9 mitigation was only reduced by a moderate 14.2%. Across the lagoon the sedimentary 3 0 DBD showed strong (R 2 = 0.85, P < 0.001) to moderate (R 2 = 0.67, P < 0.001) linear 3 1 correlations with seagrass and mangrove [TOC] respectively, moderate correlations with 3 2

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Blue carbon additionality: New insights from the radiocarbon content of saltmarsh soils and their respired CO₂

Houston,

Garnett,

Austin

2024

Limnology & Oceanography

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International policy frameworks recognize the net drawdown and storage of atmospheric greenhouse gases through management interventions on blue carbon ecosystems (saltmarshes, mangroves, seagrasses) as potential emissions offset strategies. However, key questions remain around the “additionality” of the carbon sequestered by these ecosystems, and whether some fraction of the organic carbon (OC) that does not derive from in situ production (allochthonous) should be included in carbon budgets. This study compares the radiocarbon (14C) contents of saltmarsh soils and CO2 evolved from aerobic laboratory incubations to show that young OC is preferentially respired over aged OC, and that the latter is also vulnerable to remineralization under oxic conditions. This highlights that management interventions which reduce the exposure of saltmarsh soils to oxic conditions support the inclusion of some portion of allochthonous OC in carbon budgets. Elevated temperature incubations provide preliminary evidence that the predominant source of respired OC will not change under predicted future warmer conditions. Saltmarsh typology also influences the 14C content of both the bulk soil and respired CO2, highlighting the importance of site selection for optimized blue carbon additionality.

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Accounting for black carbon lowers estimates of blue carbon storage services

Cited by 45 publications

References 39 publications

Blue carbon sequestration dynamics within tropical seagrass sediments: Long-term incubations for changes over climatic scales

Blue carbon sequestration dynamics within tropical seagrass sediments: Long-term incubations for changes over climatic scales

Valuing Carbon Stocks across a Tropical Lagoon after Accounting for Black and Inorganic Carbon: Bulk Density Proxies for monitoring

Blue carbon additionality: New insights from the radiocarbon content of saltmarsh soils and their respired CO₂

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Accounting for black carbon lowers estimates of blue carbon storage services

Cited by 45 publications

References 39 publications

Blue carbon sequestration dynamics within tropical seagrass sediments: Long-term incubations for changes over climatic scales

Blue carbon sequestration dynamics within tropical seagrass sediments: Long-term incubations for changes over climatic scales

Valuing Carbon Stocks across a Tropical Lagoon after Accounting for Black and Inorganic Carbon: Bulk Density Proxies for monitoring

Blue carbon additionality: New insights from the radiocarbon content of saltmarsh soils and their respired CO2

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Resources

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Blue carbon additionality: New insights from the radiocarbon content of saltmarsh soils and their respired CO₂