39 results on '"Macreadie, Peter"'
Search Results
2. The Evolution of Blue Carbon Science
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Duarte de Paula Costa, Micheli and Macreadie, Peter I.
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- 2022
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3. A preliminary estimate of the contribution of coastal blue carbon to climate change mitigation in New Zealand.
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Ross, Finnley W. R., Clark, Dana E., Albot, Olga, Berthelsen, Anna, Bulmer, Richard, Crawshaw, Josie, and Macreadie, Peter I.
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SEAGRASS restoration ,CLIMATE change adaptation ,CLIMATE change mitigation ,MANGROVE forests ,SALT marshes ,MANGROVE plants - Abstract
The scale at which New Zealand is currently storing and sequestering blue carbon, and could create additional blue carbon via restoration, has been unclear. Here, we calculate a preliminary estimate for the current extent of three key blue carbon ecosystems (saltmarshes, mangrove forests and seagrass meadows), their carbon stocks and their carbon sequestration rates using the best available data to provide a preliminary estimate of blue carbon in New Zealand. We also use local examples to explore opportunities to create additional blue carbon. Based on the available literature, we estimate the current extent of New Zealand's blue carbon ecosystems to be 76,152 ha, which is 1.0% of the area of terrestrial native forests. Our preliminary estimate of New Zealand's blue carbon stock is 2.66–3.76 Mt of carbon, with a current carbon sequestration rate of 0.12 (0.05–0.26) Mt/CO
2 /yr, which is equivalent to 0.16% of New Zealand's 2021 gross emissions. Restoration of saltmarshes could enhance their carbon sink capacity, mangrove forests are naturally expanding and seagrass meadow restoration techniques at scale are still in development. Developing a national framework for blue carbon protection, monitoring and restoration is important as part of New Zealand's climate change mitigation and adaptation efforts. [ABSTRACT FROM AUTHOR]- Published
- 2024
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4. It's time to broaden what we consider a 'blue carbon ecosystem'.
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James, Kelly, Macreadie, Peter I., Burdett, Heidi L., Davies, Ian, and Kamenos, Nicholas A.
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CORAL reefs & islands , *TIDAL flats , *ECOSYSTEMS , *SALT marshes , *CARBON cycle , *MANGROVE forests , *MARINE ecology , *SEAGRASSES - Abstract
Photoautotrophic marine ecosystems can lock up organic carbon in their biomass and the associated organic sediments they trap over millennia and are thus regarded as blue carbon ecosystems. Because of the ability of marine ecosystems to lock up organic carbon for millennia, blue carbon is receiving much attention within the United Nations' 2030 Agenda for Sustainable Development as a nature‐based solution (NBS) to climate change, but classically still focuses on seagrass meadows, mangrove forests, and tidal marshes. However, other coastal ecosystems could also be important for blue carbon storage, but remain largely neglected in both carbon cycling budgets and NBS strategic planning. Using a meta‐analysis of 253 research publications, we identify other coastal ecosystems—including mud flats, fjords, coralline algal (rhodolith) beds, and some components or coral reef systems—with a strong capacity to act as blue carbon sinks in certain situations. Features that promote blue carbon burial within these 'non‐classical' blue carbon ecosystems included: (1) balancing of carbon release by calcification via carbon uptake at the individual and ecosystem levels; (2) high rates of allochthonous organic carbon supply because of high particle trapping capacity; (3) high rates of carbon preservation and low remineralization rates; and (4) location in depositional environments. Some of these features are context‐dependent, meaning that these ecosystems were blue carbon sinks in some locations, but not others. Therefore, we provide a universal framework that can evaluate the likelihood of a given ecosystem to behave as a blue carbon sink for a given context. Overall, this paper seeks to encourage consideration of non‐classical blue carbon ecosystems within NBS strategies, allowing more complete blue carbon accounting. [ABSTRACT FROM AUTHOR]
- Published
- 2024
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5. Seagrasses produce most of the soil blue carbon in three Maldivian islands.
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Macreadie, Peter I., Wartman, Melissa, Roe, Philippa, Hodge, Jessica M., Helber, Stephanie B., Waryszak, Pawel, and Raoult, Vincent
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SEAGRASSES ,MANGROVE plants ,CARBON in soils ,CARBON sequestration ,PALMS ,CARBON emissions ,STABLE isotopes ,ISLANDS - Abstract
Blue carbon is fast garnering international interest for its disproportionate contribution to global carbon stocks. However, our understanding of the size of these blue carbon stocks, as well as the provenance of carbon that is stored within them, is still poor. This is especially pertinent for many small-island nations that may have substantial blue carbon ecosystems that are poorly studied. Here, we present a preliminary assessment of blue carbon from three islands in the Maldives. The higher purpose of this research was to assess the feasibility of using blue carbon to help offset carbon emissions associated with Maldivian tourism, the largest Maldivian industry with one of the highest destination-based carbon footprints, globally. We used stable isotope mixing models to identify how habitats contributed to carbon found in sediments, and Loss on Ignition (LoI) to determine carbon content. We found that for the three surveyed islands, seagrasses (Thalassia hemprichii, Thalassodendron ciliatum, Halodule pinofilia, Syringodium isoetifolium, and Cymodocea rotundata) were the main contributors to sediment blue carbon (55 - 72%) while mangroves had the lowest contribution (9 - 44%). Surprisingly, screw pine (Pandanus spp.), a relative of palm trees found across many of these islands, contributed over a quarter of the carbon found in sediments. Organic carbon content ('blue carbon') was 6.8 ± 0.3 SE % and 393 ± 29 tonnes ha
-1 for mangrove soils, and 2.5 ± 0.2% and 167 ± 20 tonnes ha-1 for seagrasses, which is slightly higher than global averages. While preliminary, our results highlight the importance of seagrasses as carbon sources in Maldivian blue carbon ecosystems, and the possible role that palms such as screw pines may have in supplementing this. Further research on Maldivian blue carbon ecosystems is needed to: 1) map current ecosystem extent and opportunities for additionality through conservation and restoration; 2) determine carbon sequestration rates; and 3) investigate options and feasibility for tourism-related blue carbon crediting. Overall, the opportunity for blue carbon in the Maldives is promising, but the state of knowledge is very limited. [ABSTRACT FROM AUTHOR]- Published
- 2024
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6. Blue carbon sink capacity of mangroves determined by leaves and their associated microbiome.
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Lu, Zhe, Qin, Guoming, Gan, Shuchai, Liu, Hongbin, Macreadie, Peter I., Cheah, Wee, and Wang, Faming
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MANGROVE plants ,CARBON cycle ,MANGROVE ecology ,CARBON sequestration ,STARCH metabolism ,BIOGEOCHEMICAL cycles ,CARBON in soils - Abstract
Copyright of Global Change Biology is the property of Wiley-Blackwell and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)
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- 2024
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7. Response to Gallagher (2022)—the Australian Tidal Restoration for Blue Carbon method 2022—conservative, robust, and practical.
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Lovelock, Catherine E., Adame, Maria Fernanda, Dittmann, Sabine, Hagger, Valerie, Hickey, Sharyn M., Hutley, Lindsay I., Jones, Alice, Kelleway, Jeffrey J., Lavery, Paul S., Macreadie, Peter I., Maher, Damien T., Mosley, Luke, Rogers, Kerrylee, and Sippo, James Z.
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WETLANDS ,WETLAND soils ,GREENHOUSE gases ,CARBON in soils ,CARBON - Abstract
The Blue Carbon Accounting Model (BlueCAM) is a tool for tidal restoration projects established under the Tidal Restoration for Blue Carbon method (2022) of the Australian voluntary carbon market. The commentary of Gallagher discussed that BlueCAM did not subtract allochthonous carbon, which is carbon in wetland soils from external sources, either terrestrial or marine sources, from estimated net abatement. This approach was used because all organic carbon preserved in a restored wetland soil, irrespective of its source, is deposited because the wetland was restored, and thus all carbon preserved above the baseline is "additional." As restoration projects develop, further characterization of different soil carbon fractions as suggested by Gallagher may improve BlueCAM. BlueCAM is transparent, conservative, and importantly is feasible for implementation, as well as being consistent with the Intergovernmental Panel for Climate Change guidelines for National Greenhouse Gas Inventories and the Australian legislative offsets integrity standards. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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8. Variability and Vulnerability of Coastal ‘Blue Carbon’ Stocks: A Case Study from Southeast Australia
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Ewers Lewis, Carolyn J., Carnell, Paul E., Sanderman, Jonathan, Baldock, Jeffrey A., and Macreadie, Peter I.
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- 2018
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9. Potential role of seaweeds in climate change mitigation
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Ross, Finnley W.R., Boyd, Philip W., Filbee-Dexter, Karen, Watanabe, Kenta, Ortega, Alejandra, Krause-Jensen, Dorte, Lovelock, Catherine, Sondak, Calvyn F.A., Bach, Lennart T., Duarte, Carlos M., Serrano, Oscar, Beardall, John, Tarbuck, Patrick, and Macreadie, Peter I.
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Carbon sequestration ,Blue carbon ,Environmental Engineering ,Macroalgae ,Environmental Chemistry ,Kelp restoration ,Aquaculture ,Conservation ,Pollution ,Waste Management and Disposal - Abstract
Seaweed (macroalgae) has attracted attention globally given its potential for climate change mitigation. A topical and contentious question is: Can seaweeds' contribution to climate change mitigation be enhanced at globally meaningful scales? Here, we provide an overview of the pressing research needs surrounding the potential role of seaweed in climate change mitigation and current scientific consensus via eight key research challenges. There are four categories where seaweed has been suggested to be used for climate change mitigation: 1) protecting and restoring wild seaweed forests with potential climate change mitigation co-benefits; 2) expanding sustainable nearshore seaweed aquaculture with potential climate change mitigation co-benefits; 3) offsetting industrial CO2 emissions using seaweed products for emission abatement; and 4) sinking seaweed into the deep sea to sequester CO2. Uncertainties remain about quantification of the net impact of carbon export from seaweed restoration and seaweed farming sites on atmospheric CO2. Evidence suggests that nearshore seaweed farming contributes to carbon storage in sediments below farm sites, but how scalable is this process? Products from seaweed aquaculture, such as the livestock methane-reducing seaweed Asparagopsis or low carbon food resources show promise for climate change mitigation, yet the carbon footprint and emission abatement potential remains unquantified for most seaweed products. Similarly, purposely cultivating then sinking seaweed biomass in the open ocean raises ecological concerns and the climate change mitigation potential of this concept is poorly constrained. Improving the tracing of seaweed carbon export to ocean sinks is a critical step in seaweed carbon accounting. Despite carbon accounting uncertainties, seaweed provides many other ecosystem services that justify conservation and restoration and the uptake of seaweed aquaculture will contribute to the United Nations Sustainable Development Goals. However, we caution that verified seaweed carbon accounting and associated sustainability thresholds are needed before large-scale investment into climate change mitigation from seaweed projects.
- Published
- 2023
10. An Australian blue carbon method to estimate climate change mitigation benefits of coastal wetland restoration.
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Lovelock, Catherine E., Adame, Maria F., Bradley, Jennifer, Dittmann, Sabine, Hagger, Valerie, Hickey, Sharyn M., Hutley, Lindsay B., Jones, Alice, Kelleway, Jeffrey J., Lavery, Paul S., Macreadie, Peter I., Maher, Damien T., McGinley, Soraya, McGlashan, Alice, Perry, Sarah, Mosley, Luke, Rogers, Kerrylee, and Sippo, James Z.
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COASTAL wetlands ,WETLAND restoration ,CLIMATE change mitigation ,CARBON sequestration ,CARBON in soils ,CARBON ,PLANT communities - Abstract
Restoration of coastal wetlands has the potential to deliver both climate change mitigation, called blue carbon, and adaptation benefits to coastal communities, as well as supporting biodiversity and providing additional ecosystem services. Valuing carbon sequestration may incentivize restoration projects; however, it requires development of rigorous methods for quantifying blue carbon sequestered during coastal wetland restoration. We describe the development of a blue carbon accounting model (BlueCAM) used within the Tidal Restoration of Blue Carbon Ecosystems Methodology Determination 2022 of the Emissions Reduction Fund (ERF), which is Australia's voluntary carbon market scheme. The new BlueCAM uses Australian data to estimate abatement from carbon and greenhouse gas sources and sinks arising from coastal wetland restoration (via tidal restoration) and aligns with the Intergovernmental Panel for Climate Change guidelines for national greenhouse gas inventories. BlueCAM includes carbon sequestered in soils and biomass and avoided emissions from alternative land uses. A conservative modeled approach was used to provide estimates of abatement (as opposed to on‐ground measurements); and in doing so, this will reduce the costs associated with monitoring and verification for ERF projects and may increase participation in blue carbon projects by Australian landholders. BlueCAM encompasses multiple climate regions and plant communities and therefore may be useful to others outside Australia seeking to value blue carbon benefits from coastal wetland restoration. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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11. Sedimentary Factors are Key Predictors of Carbon Storage in SE Australian Saltmarshes
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Kelleway, Jeffrey J., Saintilan, Neil, Macreadie, Peter I., and Ralph, Peter J.
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- 2016
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12. Pathways for Understanding Blue Carbon Microbiomes with Amplicon Sequencing.
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Hurtado-McCormick, Valentina, Trevathan-Tackett, Stacey M., Bowen, Jennifer L., Connolly, Rod M., Duarte, Carlos M., and Macreadie, Peter I.
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MICROBIAL ecology ,CARBON cycle ,ECOSYSTEMS ,CARBON ,SALT marshes ,CARBON in soils ,NUTRIENT cycles - Abstract
The capacity of Blue Carbon Ecosystems to act as carbon sinks is strongly influenced by the metabolism of soil-associated microbes, which ultimately determine how much carbon is accumulated or returned to the atmosphere. The rapid evolution of sequencing technologies has facilitated the generation of tremendous amounts of data on what taxa comprise belowground microbial assemblages, largely available as isolated datasets, offering an opportunity for synthesis research that informs progress on understanding Blue Carbon microbiomes. We identified questions that can be addressed with a synthesis approach, including the high variability across datasets, space, and time due to differing sampling techniques, ecosystem or vegetation specificity, and the relationship between microbiome community and edaphic properties, particularly soil carbon. To address these questions, we collated 34 16S rRNA amplicon sequencing datasets, including bulk soil or rhizosphere from seagrass, mangroves, and saltmarshes within publicly available repositories. We identified technical and theoretical challenges that precluded a synthesis of multiple studies with currently available data, and opportunities for addressing the knowledge gaps within Blue Carbon microbial ecology going forward. Here, we provide a standardisation toolbox that supports enacting tasks for the acquisition, management, and integration of Blue Carbon-associated sequencing data and metadata to potentially elucidate novel mechanisms behind Blue Carbon dynamics. [ABSTRACT FROM AUTHOR]
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- 2022
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13. Investing in Blue Natural Capital to secure a future for the Red Sea ecosystems
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Cziesielski, Maha Joana, Duarte, Carlos M., Aalismail, Nojood A, Al-Hafedh, Yousef, Anton, Andrea, Baalkhuyur, Faiyah, Baker, Andrew C, Balke, Thorsten, Baums, Iliana B, Berumen, Michael Lee, Chalastani, Vasiliki I., Cornwell, Brendan, Daffonchio, Daniele, Diele, Karen, Ehtsaam, Farooq, Gattuso, Jean-Pierre, He, Song, Lovelock, Catherine, Mcleod, Elizabeth, Macreadie, Peter Ian, Marba, Nuria, Martin, Cecilia, Barreto, Marcelle Muniz, Krishnakumar, Periyadan K, Prihartato, Perdana, Rabaoui, Lotfi, Saderne, Vincent, Schmidt-Roach, Sebastian, Suggett, David, Sweet, Michael, Statton, John, Teicher, Sam, Trevathan-Tackett, Stacey Marie, Joydas, Thadickal V, Aranda, Razan Ziyad Yahya and Manuel, Laboratoire d'océanographie de Villefranche (LOV), Institut national des sciences de l'Univers (INSU - CNRS)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Institut de la Mer de Villefranche (IMEV), and Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)
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[SDU.OCEAN]Sciences of the Universe [physics]/Ocean, Atmosphere ,Blue carbon ,[SDE.MCG]Environmental Sciences/Global Changes ,Marine policy ,Red Sea ecosystems ,blue economy ,coral reefs ,sustainability ,[SDU.ENVI]Sciences of the Universe [physics]/Continental interfaces, environment ,[SDE.ES]Environmental Sciences/Environmental and Society ,[SDU.STU.OC]Sciences of the Universe [physics]/Earth Sciences/Oceanography ,Environmental Policy - Abstract
International audience; Word count: 295
- Published
- 2021
14. Current and future carbon stocks in coastal wetlands within the Great Barrier Reef catchments.
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Duarte de Paula Costa, Micheli, Lovelock, Catherine E., Waltham, Nathan J., Young, Mary, Adame, Maria F., Bryant, Catherine V., Butler, Don, Green, David, Rasheed, Michael A., Salinas, Cristian, Serrano, Oscar, York, Paul H., Whitt, Ashley A., and Macreadie, Peter I.
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COASTAL wetlands ,WETLAND soils ,REEFS ,SALT marshes ,SEAGRASSES ,MARINE sediments - Abstract
Australia's Great Barrier Reef (GBR) catchments include some of the world's most intact coastal wetlands comprising diverse mangrove, seagrass and tidal marsh ecosystems. Although these ecosystems are highly efficient at storing carbon in marine sediments, their soil organic carbon (SOC) stocks and the potential changes resulting from climate impacts, including sea level rise are not well understood. For the first time, we estimated SOC stocks and their drivers within the range of coastal wetlands of GBR catchments using boosted regression trees (i.e. a machine learning approach and ensemble method for modelling the relationship between response and explanatory variables) and identified the potential changes in future stocks due to sea level rise. We found levels of SOC stocks of mangrove and seagrass meadows have different drivers, with climatic variables such as temperature, rainfall and solar radiation, showing significant contributions in accounting for variation in SOC stocks in mangroves. In contrast, soil type accounted for most of the variability in seagrass meadows. Total SOC stock in the GBR catchments, including mangroves, seagrass meadows and tidal marshes, is approximately 137 Tg C, which represents 9%–13% of Australia's total SOC stock while encompassing only 4%–6% of the total extent of Australian coastal wetlands. In a global context, this could represent 0.5%–1.4% of global SOC stock. Our study suggests that landward migration due to projected sea level rise has the potential to enhance carbon accumulation with total carbon gains between 0.16 and 0.46 Tg C and provides an opportunity for future restoration to enhance blue carbon. [ABSTRACT FROM AUTHOR]
- Published
- 2021
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15. Factors Determining Seagrass Blue Carbon Across Bioregions and Geomorphologies.
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Mazarrasa, Inés, Lavery, Paul, Duarte, Carlos M., Lafratta, Anna, Lovelock, Catherine E., Macreadie, Peter I., Samper‐Villarreal, Jimena, Salinas, Cristian, Sanders, Christian J., Trevathan‐Tackett, Stacey, Young, Mary, Steven, Andy, and Serrano, Oscar
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SEAGRASSES ,SOLAR radiation ,CARBON in soils ,GREENHOUSE gases ,CARBON ,ZOSTERA ,GEOMORPHOLOGY - Abstract
Seagrass meadows rank among the most significant organic carbon (Corg) sinks on earth. We examined the variability in seagrass soil Corg stocks and composition across Australia and identified the main drivers of variability, applying a spatially hierarchical approach that incorporates bioregions and geomorphic settings. Top 30 cm soil Corg stocks were similar across bioregions and geomorphic settings (min‐max: 20–26 Mg Corg ha−1), but meadows formed by large species (i.e., Amphibolis spp. and Posidonia spp.) showed higher stocks (24–29 Mg Corg ha−1) than those formed by smaller species (e.g., Halodule, Halophila, Ruppia, Zostera, Cymodocea, and Syringodium; 12–21 Mg Corg ha−1). In temperate coastal meadows dominated by large species, soil Corg stocks mainly derived from seagrass Corg (72 ± 2%), while allochthonous Corg dominated soil Corg stocks in meadows formed by small species in temperate and tropical estuarine meadows (64 ± 5%). In temperate coastal meadows, soil Corg stocks were enhanced by low hydrodynamic exposure associated with high mud and seagrass Corg contents. In temperate estuarine meadows, soil Corg stocks were enhanced by high contributions of seagrass Corg, low to moderate solar radiation, and low human pressure. In tropical estuarine meadows formed by small species, large soil Corg stocks were mainly associated with low hydrodynamic energy, low rainfall, and high solar radiation. These results showcase that bioregion and geomorphic setting are not necessarily good predictors of soil Corg stocks and that site‐specific estimates based on local environmental factors are needed for Blue Carbon projects and greenhouse gases accounting purposes. Key Points: Australian seagrasses contain higher soil organic carbon stocks than adjacent unvegetated areas due to higher seagrass inputsSeagrass soil carbon stocks are similar over bioregions and geomorphic settings but higher in larger species compared to smaller speciesFactors determining seagrass soil carbon stocks differ across bioregions and coastal geomorphic settings within bioregions [ABSTRACT FROM AUTHOR]
- Published
- 2021
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16. Modelling of fatty acids signatures predicts macroalgal carbon in marine sediments.
- Author
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Erlania, Macreadie, Peter I., Francis, David S., and Bellgrove, Alecia
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MARINE sediments , *FATTY acids , *MARINE algae , *CARBON sequestration , *CARBON , *MANGROVE plants , *MACROPHYTES - Abstract
[Display omitted] • Biomarkers to identify and quantify carbon contributors to sequestration are needed. • Use of complete sets of fatty acid (FA) profiles are novel to biomarker discovery. • XGBoost models of FA profiles discriminated seaweed carbon from other sources. • High predictive accuracies of this biomarker approach may facilitate quantification. • Quantifying seaweed contributions to blue carbon sequestration may soon be feasible. Differentiating between carbon contributors in marine environments is crucial to gaining a deeper understanding of marine carbon sequestration, and some efforts have been made through the application of various approaches. This study proposed a new approach through the use of fatty acid (FA) profiles of six marine macrophytes within three macroalgal lineages, and three coastal angiosperms (mangrove, saltmarsh, and seagrass). We compiled FA profiles (consisting of 84 individuals and 9 classes/groups of FAs) of 544 Australian coastal macrophyte species identified in published reports. The data were gradually screened into three different datasets (full-84FA, reduced-57FA, and reduced-48FA) for analysis to minimise the effects of imbalanced distributions of data on analysis. XGBoost (eXtreme Gradient Boosting) multiclass classification modelling with hyperparameter tuning was applied to reveal the specific FA signatures of each macrophyte lineage. The XGBoost models run across the three datasets generated high model-performance metrics including precision, recall, F-score, and multiclass-AUC, indicating similar performance between the three models with predictive accuracies of 94%, 85%, and 95%, respectively. At the class level, the three models also demonstrated high performance with precision, recall, and F-score values for each lineage above 0.95, except for Rhodophyta, which ranged from around 0.80 to 0.89. Overall, our findings suggest that the XGBoost classifier can reveal the lineage-specific patterns of FAs (carbon-based molecules) that can be implemented to predict and potentially quantify the carbon contributors to marine sediments, and more specifically, to discern macroalgal carbon contributions from those of other coastal macrophytes. [ABSTRACT FROM AUTHOR]
- Published
- 2024
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17. Spatially explicit ecosystem accounts for coastal wetland restoration.
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D. P. Costa, Micheli, Wartman, Melissa, Macreadie, Peter I., Ferns, Lawrance W., Holden, Rhiannon L., Ierodiaconou, Daniel, MacDonald, Kimberley J., Mazor, Tessa K., Morris, Rebecca, Nicholson, Emily, Pomeroy, Andrew, Zavadil, Elisa A., Young, Mary, Snartt, Rohan, and Carnell, Paul
- Abstract
• The combined benefit of existing coastal wetlands can reach approximately AUD120.9 billion per year. • Fencing is the cheapest management action to restore coastal wetlands, delivering more than AUD140 billion after 50 years. • Despite having the highest cost, tidal reinstatement combined with managed retreat can deliver the highest benefit. Coastal wetlands (i.e., mangroves, saltmarshes, and seagrasses) have been recognised as an efficient natural climate solution to help mitigate and adapt to climate change. These ecosystems are also known to provide additional ecosystem services to coastal communities (e.g., fisheries and biodiversity enhancement, nutrient removal). Despite their importance to coasts and coastal communities, we lack spatially explicit information on the values of these ecosystems and the estimated return on investment from coastal management activities to rehabilitate them. Here, we aligned an environmental economic accounting framework combined with a scenario analysis to develop a set of accounts for mangroves, saltmarshes, and seagrasses across the state of Victoria (Australia) as a case study, including the following ecosystem services: commercial and recreational fisheries, carbon and nitrogen sequestration, and coastal hazard mitigation. Importantly, we assessed the current extent, condition, and ecosystem services (physical and monetary) from these coastal ecosystems and examined how they could be improved through management actions. Overall, we found that the combined benefit (i.e., nitrogen and carbon sequestration, fisheries, and coastal hazard mitigation) provided by existing mangroves, saltmarshes, and seagrasses in Victoria is approximately AUD120.9 billion per year. Considering the management scenarios included in this study, our analysis showed that levee removal plus managed retreat had the highest cost at AUD7.6 billion; however, it also provided the highest net benefit of AUD134.8 trillion after 50 years, with a 5 % discount rate. In contrast, fencing was the cheapest management action to restore mangroves and saltmarshes, delivering more than AUD140 billion after 50 years. While our results demonstrate a large return on investment if coastal wetlands are restored at large scale, the implementation of small-scale projects is still a major challenge. However, this study demonstrates that an environmental economic accounting framework combined with a scenario analysis is a powerful approach to guide the decision-making process, providing critical information on the estimated return-on-investment from restoration of mangroves and saltmarshes, with encouraging implications of the impacts of actions at local scales. [ABSTRACT FROM AUTHOR]
- Published
- 2024
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18. Predators Shape Sedimentary Organic Carbon Storage in a Coral Reef Ecosystem
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Atwood, Trisha Brooke, Madin, Elizabeth M. P., Harborne, Alastair R., Hammill, Edd, Luiz, Osmar J., Ollivier, Quinn R., Roelfsema, Chris M., Macreadie, Peter I., Lovelock, Catherine E., and Frontiers
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predators ,Great Barrier Reef ,herbivory ,blue carbon ,trait-mediated effects ,Ecology and Evolutionary Biology ,technology, industry, and agriculture ,trophic cascades ,Life Sciences ,coral reefs ,grazing halos - Abstract
Trophic cascade theory predicts that predator effects should extend to influence carbon cycling in ecosystems. Yet, there has been little empirical evidence in natural ecosystems to support this hypothesis. Here, we use a naturally-occurring trophic cascade to provide evidence that predators help protect sedimentary organic carbon stocks in coral reef ecosystems. Our results show that predation risk altered the behavior of herbivorous fish, whereby it constrained grazing to areas close to the refuge of the patch reefs. Macroalgae growing in “riskier” areas further away from the reef were released from grazing pressure, which subsequently promoted carbon accumulation in the sediments underlying the macroalgal beds. Here we found that carbon stocks furthest away from the reef edge were ~24% higher than stocks closest to the reef. Our results indicate that predators and herbivores play an important role in structuring carbon dynamics in a natural marine ecosystem, highlighting the need to conserve natural predator-prey dynamics to help maintain the crucial role of marine sediments in sequestering carbon.
- Published
- 2018
19. Carbon stocks, sequestration, and emissions of wetlands in south eastern Australia.
- Author
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Carnell, Paul E., Windecker, Saras M., Brenker, Madeline, Baldock, Jeff, Masque, Pere, Brunt, Kate, and Macreadie, Peter I.
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WETLANDS ,CARBON sequestration ,CARBON dioxide mitigation ,GLOBAL warming ,ENVIRONMENTAL protection - Abstract
Abstract: Nontidal wetlands are estimated to contribute significantly to the soil carbon pool across the globe. However, our understanding of the occurrence and variability of carbon storage between wetland types and across regions represents a major impediment to the ability of nations to include wetlands in greenhouse gas inventories and carbon offset initiatives. We performed a large‐scale survey of nontidal wetland soil carbon stocks and accretion rates from the state of Victoria in south‐eastern Australia—a region spanning 237,000 km
2 and containing >35,000 temperate, alpine, and semi‐arid wetlands. From an analysis of >1,600 samples across 103 wetlands, we found that alpine wetlands had the highest carbon stocks (290 ± 180 Mg Corg ha−1 ), while permanent open freshwater wetlands and saline wetlands had the lowest carbon stocks (110 ± 120 and 60 ± 50 Mg Corg ha−1 , respectively). Permanent open freshwater sites sequestered on average three times more carbon per year over the last century than shallow freshwater marshes (2.50 ± 0.44 and 0.79 ± 0.45 Mg Corg ha−1 year−1 , respectively). Using this data, we estimate that wetlands in Victoria have a soil carbon stock in the upper 1 m of 68 million tons of Corg , with an annual soil carbon sequestration rate of 3 million tons of CO2 eq. year−1 —equivalent to the annual emissions of about 3% of the state's population. Since European settlement (~1834), drainage and loss of 260,530 ha of wetlands may have released between 20 and 75 million tons CO2 equivalents (based on 27%–90% of soil carbon converted to CO2 ). Overall, we show that despite substantial spatial variability within wetland types, some wetland types differ in their carbon stocks and sequestration rates. The duration of water inundation, plant community composition, and allochthonous carbon inputs likely play an important role in influencing variation in carbon storage. [ABSTRACT FROM AUTHOR]- Published
- 2018
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20. Effects of small‐scale, shading‐induced seagrass loss on blue carbon storage: Implications for management of degraded seagrass ecosystems.
- Author
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Trevathan‐Tackett, Stacey M., Wessel, Caitlin, Cebrián, Just, Ralph, Peter J., Masqué, Pere, and Macreadie, Peter I.
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SEAGRASSES ,GLOBAL warming ,CARBON ,MARINE plants ,AQUATIC plants - Abstract
Abstract: Seagrass meadows are important global blue carbon sinks. Despite a 30% loss of seagrasses globally during the last century, there is limited empirical research investigating the effects of disturbance and loss of seagrass on blue carbon stocks. In this study, we hypothesised that seagrass loss would reduce blue carbon stocks. Using shading cloth, we simulated small‐scale die‐offs of two subtropical seagrass species,
Halodule wrightii andThalassia testudinum , in a dynamic northern Gulf of Mexico lagoon. The change in quantity and quality of sediment organic matter (OM) and organic carbon was compared among die‐off, control and bare plots before the die‐off treatment, shortly after the die‐off treatment and 11 months after the die‐off treatment.210 Pb age dating was performed on bare andThalassia plots at 11 months to evaluate the impact of sediment erosion in the absence of vegetation. The small‐scale die‐off led to a 50%–65% OM loss in the sediment in the top 8 cm ofHalodule plots.Thalassia plots lost significant portions of OM (50%) and organic carbon (Corg ; 21%–47%) in only the top 1 cm of sediment. The210 Pb profiles indicatedThalassia die‐off reduced the Corg sequestration rate by 10%, in addition to a loss ofc . 1 year's worth of Corg stocks (c . 22 g/m2 ). Furthermore, analyses on OM/Corg quality indicated a loss of labile OM/Corg and enhanced remineralisation by microbes.Synthesis and applications . This study provides empirical evidence that small‐scale shading‐induced seagrass die‐offs can reduce seagrass carbon sequestration capacity and trigger losses of blue carbon stocks. While the losses recorded here are modest, these losses in blue carbon storage capacity are notable due to the proximity of shading structures (e.g. boat docks) to seagrass habitats. Thus, policies to avoid or protect seagrass habitats from common small‐scale, shading disturbances are important for optimising both carbon sequestration capacity and coastline development and management. [ABSTRACT FROM AUTHOR]- Published
- 2018
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21. Invasive cordgrass (<italic>Spartina</italic> spp.) in south‐eastern Australia induces island formation, salt marsh development, and carbon storage.
- Author
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Kennedy, David M., Konlechner, Teresa, Zavadil, Elisa, Mariani, Michela, Wong, Vanessa, Ierodiaconou, Daniel, and Macreadie, Peter
- Subjects
SPARTINA ,INVASIVE plants ,SALT marshes ,CARBON sequestration ,GEOMORPHOLOGY ,PLANTS - Abstract
Abstract: Invasive vegetation species can lead to major changes in the geomorphology of coastal systems. Within temperate estuaries in the southern hemisphere, especially Australia and New Zealand, the cordgrass Spartina spp. has become established. These species are highly invasive, and their prolific growth leads to the development of supratidal environments in formerly intertidal and subtidal environments. Here, we quantified the impact of Spartina invasion on the geomorphology and sequestration capacity of carbon in the sediments of Anderson Inlet, Victoria, Australia. Spartina was first introduced to the area in the 1930s to aid in land reclamation and control coastal erosion associated with coastal development. We found that Spartina now dominates the intertidal areas of the Inlet and promotes accretion (18 mm/year) causing the formation of over 108 ha of supratidal islands over the past 100 years. These newly formed islands are calculated to potentially contain over 5.5 million tonnes of CO
2 equivalent carbon. Future management of the inlet and other Spartina‐dominated environments within Australian presents a dilemma for resource managers; on the one hand, Spartina is highly invasive and can outcompete native tidal marshes, thereby warranting its eradication, but on the other hand it is likely more resilient to rising sea levels and has the potential for carbon sequestration. Whether or not the potential advantages outweigh the significant habitat change that is anticipated, any management strategies will likely require additional research into costs and benefits of all ecosystem services provided by Spartina including in relation to nutrient cycling, shoreline stabilisation, and biodiversity as well as in response to the longevity of carbon found within the sediments. [ABSTRACT FROM AUTHOR]- Published
- 2018
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22. Converting beach-cast seagrass wrack into biochar: A climate-friendly solution to a coastal problem.
- Author
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Macreadie, Peter I., Trevathan-Tackett, Stacey M., Baldock, Jeffrey A., and Kelleway, Jeffrey J.
- Subjects
- *
BIOCHAR , *CLIMATE change , *COASTAL development , *SEAGRASSES , *CARBON content of plants - Abstract
Excessive accumulation of plant ‘wrack’ on beaches as a result of coastal development and beach modification (e.g. groin installation) is a global problem. This study investigated the potential for converting beach-cast seagrass wrack into biochar as a ‘climate-friendly’ disposal option for resource managers. Wrack samples from 11 seagrass species around Australia were initially screened for their biochar potential using pyrolysis techniques, and then two species – Posidonia australis and Zostera muelleri – underwent detailed analyses. Both species had high levels of refractory materials and high conversion efficiency (48–57%) of plant carbon into biochar carbon, which is comparable to high-quality terrestrial biochar products. P. australis wrack gave higher biochar yields than Z. muelleri consistent with its higher initial carbon content. According to 13 C NMR, wrack predominantly comprised carbohydrates, protein, and lignin. Aryl carbon typical of pyrogenic materials dominated the spectrum of the thermally-altered organic materials. Overall, this study provides the first data on the feasibility of generating biochar from seagrass wrack, showing that biocharring offers a promising climate-friendly alternative to disposal of beach wrack in landfill by avoiding a portion of the greenhouse gas emissions that would otherwise occur if wrack was left to decompose. [ABSTRACT FROM AUTHOR]
- Published
- 2017
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23. Seventy years of continuous encroachment substantially increases 'blue carbon' capacity as mangroves replace intertidal salt marshes.
- Author
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Kelleway, Jeffrey J., Saintilan, Neil, Macreadie, Peter I., Skilbeck, Charles G., Zawadzki, Atun, and Ralph, Peter J.
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SALT marshes ,CLIMATE change ,MANGROVE forests ,BIOMASS ,CARBON sequestration ,ABSOLUTE sea level change - Abstract
Shifts in ecosystem structure have been observed over recent decades as woody plants encroach upon grasslands and wetlands globally. The migration of mangrove forests into salt marsh ecosystems is one such shift which could have important implications for global 'blue carbon' stocks. To date, attempts to quantify changes in ecosystem function are essentially constrained to climate-mediated pulses (30 years or less) of encroachment occurring at the thermal limits of mangroves. In this study, we track the continuous, lateral encroachment of mangroves into two south-eastern Australian salt marshes over a period of 70 years and quantify corresponding changes in biomass and belowground C stores. Substantial increases in biomass and belowground C stores have resulted as mangroves replaced salt marsh at both marine and estuarine sites. After 30 years, aboveground biomass was significantly higher than salt marsh, with biomass continuing to increase with mangrove age. Biomass increased at the mesohaline river site by 130 ± 18 Mg biomass km
−2 yr−1 (mean ± SE), a 2.5 times higher rate than the marine embayment site (52 ± 10 Mg biomass km−2 yr−1 ), suggesting local constraints on biomass production. At both sites, and across all vegetation categories, belowground C considerably outweighed aboveground biomass stocks, with belowground C stocks increasing at up to 230 ± 62 Mg C km−2 yr−1 (± SE) as mangrove forests developed. Over the past 70 years, we estimate mangrove encroachment may have already enhanced intertidal biomass by up to 283 097 Mg and belowground C stocks by over 500 000 Mg in the state of New South Wales alone. Under changing climatic conditions and rising sea levels, global blue carbon storage may be enhanced as mangrove encroachment becomes more widespread, thereby countering global warming. [ABSTRACT FROM AUTHOR]- Published
- 2016
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24. Variability of sedimentary organic carbon in patchy seagrass landscapes.
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Ricart, Aurora M., York, Paul H., Rasheed, Michael A., Pérez, Marta, Romero, Javier, Bryant, Catherine V., and Macreadie, Peter I.
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SEAGRASSES ,LANDSCAPES ,CARBON cycle ,CARBON sequestration ,CLIMATE change ,MARINE sediments - Abstract
Seagrass ecosystems, considered among the most efficient carbon sinks worldwide, encompass a wide variety of spatial configurations in the coastal landscape. Here we evaluated the influence of the spatial configuration of seagrass meadows at small scales (metres) on carbon storage in seagrass sediments. We intensively sampled carbon stocks and other geochemical properties (δ 13 C, particle size, depositional fluxes) across seagrass–sand edges in a Zostera muelleri patchy seagrass landscape. Carbon stocks were significantly higher (ca. 20%) inside seagrass patches than at seagrass–sand edges and bare sediments. Deposition was similar among all positions and most of the carbon was from allochthonous sources. Patch level attributes (e.g. edge distance) represent important determinants of the spatial heterogeneity of carbon stocks within seagrass ecosystems. Our findings indicate that carbon stocks of seagrass areas have likely been overestimated by not considering the influence of meadow landscapes, and have important relevance for the design of seagrass carbon stock assessments. [ABSTRACT FROM AUTHOR]
- Published
- 2015
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25. Comparison of marine macrophytes for their contributions to blue carbon sequestration.
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Trevathan-Tackett, Stacey M., Kelleway, Jeffrey, Macreadie, Peter I., Beardall, John, Ralph, Peter, and Bellgrove, Alecia
- Subjects
MARINE ecology ,CARBON sequestration ,MARINE algae ,MACROPHYTES ,THERMOGRAVIMETRY - Abstract
Many marine ecosystems have the capacity for long-term storage of organic carbon (C) in what are termed "blue carbon" systems. While blue carbon systems (saltmarsh, mangrove, and seagrass) are efficient at long-term sequestration of organic carbon (C), much of their sequestered C may originate from other (allochthonous) habitats. Macroalgae, due to their high rates of production, fragmentation, and ability to be transported, would also appear to be able to make a significant contribution as C donors to blue C habitats. In order to assess the stability of macroalgal tissues and their likely contribution to long-term pools of C, we applied thermogravimetric analysis (TGA) to 14 taxa of marine macroalgae and coastal vascular plants. We assessed the structural complexity of multiple lineages of plant and tissue types with differing cell wall structures and found that decomposition dynamics varied significantly according to differences in cell wall structure and composition among taxonomic groups and tissue function (photosynthetic vs. attachment). Vascular plant tissues generally exhibited greater stability with a greater proportion of mass loss at temperatures >300°C (peak mass loss ~320°C) than macroalgae (peak mass loss between 175-300°C), consistent with the lignocellulose matrix of vascular plants. Greater variation in thermogravimetric signatures within and among macroalgal taxa, relative to vascular plants, was also consistent with the diversity of cell wall structure and composition among groups. Significant degradation above 600°C for some macroalgae, as well as some belowground seagrass tissues, is likely due to the presence of taxon-specific compounds. The results of this study highlight the importance of the lignocellulose matrix to the stability of vascular plant sources and the potentially significant role of refractory, taxon-specific compounds (carbonates, long-chain lipids, alginates, xylans, and sulfated polysaccharides) from macroalgae and seagrasses for their long-term sedimentary C storage. This study shows that marine macroalgae do contain refractory compounds and thus may be more valuable to long-term carbon sequestration than we previously have considered. [ABSTRACT FROM AUTHOR]
- Published
- 2015
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26. A decision support tool to help identify blue carbon sites for restoration.
- Author
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Nuyts, Siegmund, Duarte de Paula Costa, Micheli, Macreadie, Peter I., and Trevathan-Tackett, Stacey M.
- Subjects
- *
CLIMATE change adaptation , *CLIMATE change mitigation , *CLIMATE change , *GEOGRAPHIC information systems , *SEAGRASS restoration - Abstract
Blue carbon ecosystems (BCEs), such as mangroves, saltmarshes, and seagrasses, are important nature-based solutions for climate change mitigation and adaptation but are threatened by degradation. Effective BCE restoration requires strategic planning and site selection to optimise outcomes. We developed a Geographic Information System (GIS)-based multi-criteria decision support tool to identify suitable areas for BCE restoration along the 2512 km-long coastline of Victoria, Australia. High-resolution spatial data on BCE distribution, coastal geomorphology, hydrodynamics, and land tenure were integrated into a flexible spatial model that distinguishes between passive and active restoration suitability. The tool was applied to identify high-priority locations for mangrove, saltmarsh, and seagrass restoration across different scenarios. Results indicate substantial potential for BCE restoration in Victoria, with 33,253 ha of suitable area identified, mostly (>97%) on public land, which aligned with the selection criteria used in the tool. Restoration opportunities are concentrated in bays and estuaries where historical losses have been significant. The mapped outputs provide a decision-support framework for regional restoration planning, while the tool itself can be adapted to other geographies. By integrating multiple spatial criteria and distinguishing between passive and active restoration, our approach offers a new method for targeting BCE restoration and informing resource allocation. The identified restoration potential will also require collaboration with coastal managers and communities, and consideration of socio-economic factors. With further refinements, such as incorporating multi-criteria decision analysis techniques, GIS-based tools can help catalyse strategic blue carbon investments and contribute to climate change mitigation and adaptation goals at different spatial scales. This study highlights the value of spatial identification for BCE restoration and provides a transferable framework for other regions. [ABSTRACT FROM AUTHOR]
- Published
- 2024
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27. Response of Seagrass 'Blue Carbon' Stocks to Increased Water Temperatures.
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Macreadie, Peter I. and Hardy, Simon S. S.
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- *
SEAGRASSES , *MARINE plants - Abstract
Seagrass meadows are globally important sinks of 'Blue Carbon', but warming water temperatures due to climate change may undermine their capacity to sequester and retain organic carbon (Corg). We tested the effects of warming on seagrass Corg stocks in situ by transplanting seagrass soil cores along a thermal plume generated by a coal-fired power plant in a seagrass-dominated estuary (Lake Macquarie, Australia). Transplanted cores were subjected to temperatures 2 and 4 °C above ambient temperatures and Corg content was measured after 7, 30, 90 and 180 days. We were unable to detect any significant effect of warming on Corg concentration, stocks, chemical composition (as measured by labile, recalcitrant, refractory ratios), or microbial abundance at any time point. In fact, Corg levels were temporally variable. These findings contrast those of previous studies (mostly laboratory-based) that have reported increases in microbial remineralisation (breakdown) of Corg in response to warming. To explain the lack of any detectable warming effect, we suggest that higher temperatures, longer durations of warming exposure, or additional stressors (e.g., oxygen exposure) may be needed to overcome microbial activation barriers and stimulate Corg remineralisation. [ABSTRACT FROM AUTHOR]
- Published
- 2018
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28. Modelling the spatiotemporal dynamics of blue carbon stocks in tidal marsh under Spartina alterniflora invasion.
- Author
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Zhao, Wenzhen, Li, Xiuzhen, Costa, Micheli D.P., Wartman, Melissa, Lin, Shiwei, Wang, Jiangjing, Yuan, Lin, Wang, Teng, Yang, Hualei, Qin, Yutao, Ji, Huanhong, and Macreadie, Peter I.
- Subjects
- *
MACHINE learning , *BIOLOGICAL invasions , *SPARTINA alterniflora , *RANDOM forest algorithms , *GOVERNMENT policy on climate change , *SALT marshes - Abstract
[Display omitted] • Machine learning reveals spatiotemporal dynamics of SOC stocks in tidal marshes. • Sediment salinity and tidal range are key factors influencing SOC stocks prediction. • Invasive S. alterniflora contributes over half of SOC stocks in Yangtze Estuary. • S. alterniflora increased SOC stocks within the first 15 years of its invasion. • S. alternifloras high SOC storage capacity is not sustained in the long term. Spatial quantification of blue carbon ecosystem stocks is crucial for developing policies to mitigate climate change, especially in regions experiencing ongoing wetland disturbance from biological invasions. We integrated multiple machine learning models with the space-for-time substitution method to quantify the spatiotemporal impact of Spartina alterniflora invasion on tidal marsh sediment blue carbon (soil organic carbon – 'SOC') stocks at 100 cm depth in the Yangtze Estuary. Our results show that the invasive S. alterniflora contributed more than half of the total SOC stocks (2,056 ± 379 Gg C, 1 Gg = 106 kg) in the 27,600 ha tidal marshes of the Yangtze Estuary, which were estimated to be 1,107 ± 176 Gg C. S. alterniflora increased the SOC stocks in the Yangtze Estuary within the first 15 years, but this gain was not sustained in the long term, with a gradual decline (by 13.14 Mg C/ha) observed after 15 years of S. alterniflora growth. We found that sediment salinity, tidal range, and human accessibility were strong indicators for modeling and predicting SOC stocks, with Random Forest providing the best simulation of tidal marsh SOC stocks (R2 = 0.894, RMSE=7.646 Mg C/ha, and MAPE=9.469 %). Our study provides much needed information on blue carbon stocks in the Yangtze Estuary under biological invasion stress, and offers guidance for targeted S. alterniflora management actions in the future. [ABSTRACT FROM AUTHOR]
- Published
- 2024
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29. Seagrass decline weakens sediment organic carbon stability.
- Author
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Ren, Yuzheng, Liu, Songlin, Luo, Hongxue, Jiang, Zhijian, Liang, Jiening, Wu, Yunchao, Huang, Xiaoping, and Macreadie, Peter I.
- Published
- 2024
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30. National scale predictions of contemporary and future blue carbon storage.
- Author
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Young, Mary A., Serrano, Oscar, Macreadie, Peter I., Lovelock, Catherine E., Carnell, Paul, and Ierodiaconou, Daniel
- Published
- 2021
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31. Temporal and spatial variations of air-sea CO2 fluxes and their key influence factors in seagrass meadows of Hainan Island, South China Sea.
- Author
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Liu, Songlin, Liang, Jiening, Jiang, Zhijian, Li, Jinlong, Wu, Yunchao, Fang, Yang, Ren, Yuzheng, Zhang, Xia, Huang, Xiaoping, and Macreadie, Peter I.
- Published
- 2024
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32. Long-term decomposition captures key steps in microbial breakdown of seagrass litter.
- Author
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Trevathan-Tackett, Stacey M., Jeffries, Thomas C., Macreadie, Peter I., Manojlovic, Bojana, and Ralph, Peter
- Abstract
Seagrass biomass represents an important source of organic carbon that can contribute to long-term sediment carbon stocks in coastal ecosystems. There is little empirical data on the long-term microbial decomposition of seagrass detritus, despite this process being one of the key drivers of carbon-cycling in coastal ecosystems, that is, it influences the amount and quality of carbon available for sequestration. Here, our goal was to investigate how litter quality (leaf vs. rhizome/root) and the microbial communities involved in organic matter remineralisation shift over a 2-year field decomposition study north of Sydney, Australia using the temperate seagrass Zostera muelleri. The sites varied in bulk sediment characteristics and the sediment-associated microbial communities, but these variables overall had little influence on long-term seagrass decomposition rates or seagrass-associated microbiomes. The results showed a clear succession of bacterial and archaeal communities for both tissues types from r -strategists such as α- and γ-proteobacteria to K -strategies, including δ-proteobacteria, Bacteroidia and Spirochaetes. We used a new mathematical model to capture how decay rates varied over time and found that two decomposition events occurred for some seagrass leaf samples, possibly due to exudate input from living seagrass roots growing into the litter bag. The new model also indicated that conventional single exponential models overestimate long-term decay rates, and we detected for the first time the refractory, or stable, phase of decomposition for rhizome/root biomass. The stable phase began at approximately 20% mass remaining and after 600 days, and the persistence of rhizome/root biomass was attributed to the anoxic conditions and the preservation of refractory organic matter. While we predict that rhizome/root biomass will contribute more to the long-term sediment carbon stocks, the preservation of leaf carbon may be enhanced at locations were sedimentation is high and burial in anoxic conditions is rapid and constant. Unlabelled Image • Long-term seagrass decay rates may be previously overestimated. • Decomposition of seagrass above- and belowground litter was measured over two years. • The stable phase of decay was captured for belowground rhizome/root litter. • Microbial community succession matches shifts in organic matter recalcitrance. • Root exudates could enhance litter remineralisation. [ABSTRACT FROM AUTHOR]
- Published
- 2020
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33. Nutrient loading weakens seagrass blue carbon potential by stimulating seagrass detritus carbon emission.
- Author
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Liu, Songlin, Luo, Hongxue, Jiang, Zhijian, Ren, Yuzheng, Zhang, Xia, Wu, Yunchao, Huang, Xiaoping, and Macreadie, Peter I.
- Subjects
- *
POSIDONIA , *CARBON emissions , *SEAGRASSES , *DETRITUS , *CARBON cycle , *BIOGEOCHEMICAL cycles - Abstract
[Display omitted] • Nutrient load elevated seagrass leaf quality but decreased refractory carbon. • High quality detritus decomposed 13% more of lignin and 80% more CO 2 emission. • Nutrient addition enhanced 48% higher CO 2 emissions of detritus. • CO 2 emissions of high quality detritus to a greater extent under nutrient addition. Coastal nutrient loading has been linked to a decline in the capacity of seagrass ecosystems to sequester carbon ('blue carbon'); however, the mechanisms are unclear. Here we investigated how nutrient loading can affect the contribution that seagrass plant material makes to blue carbon stocks by investigating plant quality-decomposition dynamics. Specifically, we used a combination of laboratory and field experiments to account for various changes in biogeochemical cycling from seagrass meadows, ranging from changes in leaf quality to CO 2 fluxes. It was found that nutrient loading increased the 'labile' content of seagrass (i.e. increased levels of leaf nitrogen, phosphorus and soluble organic carbon (amino acid and soluble sugar content), and at the same time decreased levels of 'recalcitrant' carbon (i.e. materials that are harder for microbes to break down, such hemicellulose, cellulose and lignin contents). Nutrient-enriched leaves decomposed ∼ 18 % faster than non-enriched leaves (i.e. greater biomass loss from nutrient-affected seagrass), resulting in ∼ 80 % more CO 2 emissions from nutrient-enriched seagrass. We also found that seagrass that naturally contained high levels of labile carbon at the start of the experiment were affected to a greater degree (i.e. higher CO 2 emissions) by nutrients addition than seagrass that had high proportions of recalcitrant carbon to begin with. Overall, these findings suggest that nutrient loading can weaken the capacity of seagrass ecosystems to act as blue carbon sinks through its effect on seagrass leaf decomposability. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
34. Mapping trade-offs among key ecosystem functions in tidal marsh to inform spatial management policy for exotic Spartina alterniflora.
- Author
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Zhao, Wenzhen, Li, Xiuzhen, Xue, Liming, Lin, Shiwei, Ma, Yuxi, Su, Lin, Li, Zeyuan, Gong, Lv, Yan, Zhongzheng, and Macreadie, Peter I.
- Subjects
- *
SPARTINA alterniflora , *SALT marshes , *COASTAL wetlands , *ECOSYSTEMS , *WAVE energy , *ROGUE waves , *FULLERENES - Abstract
Invasive Spartina alterniflora has become a global management challenge in coastal wetlands. China has decided to eradicate it completely, but the high costs and its provision of beneficial ecosystem functions (EF, in the form of blue carbon and coastal protection) have raised concerns about its removal. Here, using the Yangtze Estuary as a case study, we explore a reasonable pathway of S. alterniflora management that balanced control of invasive species and EF. We simulated the spatial patterns of two key EF – blue carbon storage and wave attenuation – and identified appropriate zones for eradicating S. alterniflora based on their trade-offs. We observed contrasting patterns along the land-sea gradient for S. alterniflora community, with a decrease in blue carbon storage and an increase in wave attenuation. Notably, pioneer S. alterniflora near the foreshore displayed a high cluster of blue carbon storage (63.61 ± 7.33 Mg C ha−1) and dissipated nearly 70% of wave energy by a width of 163 m. The trade-offs between the two EF indicated that the eradication project should be implemented along the seawall rather than the foreshore. Even in the scenario of prioritized shore defense with the largest eradication zone, S. alterniflora still stored 43.1% more carbon (10.67 Gg C) compared to complete eradication and dissipated over 70% of wave energy in extreme events. Our study innovatively integrates eradication and reservation in S. alterniflora management, providing a sustainable and flexible spatial strategy that meets the needs of stakeholders. • Quantified coastal ecosystem functions with complex processes from space. • Invasive Spartina significantly enhances ecosystem functions in the foreshore. • Eradication project of Spartina should be implemented towards landward side. • Setting optimal Spartina zone width enhances coastal wetlands' ecosystem function. • Wise management of Spartina with eradication and reservation. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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- View/download PDF
35. Impacts of land reclamation on tidal marsh 'blue carbon' stocks.
- Author
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Ewers Lewis, Carolyn J., Baldock, Jeffrey A., Hawke, Bruce, Gadd, Patricia S., Zawadzki, Atun, Heijnis, Henk, Jacobsen, Geraldine E., Rogers, Kerrylee, and Macreadie, Peter I.
- Abstract
Tidal marsh ecosystems are among earth's most efficient natural organic carbon (C) sinks and provide myriad ecosystem services. However, approximately half have been 'reclaimed' – i.e. converted to other land uses – potentially turning them into sources of greenhouse gas emissions. In this study, we applied C stock measurements and paleoanalytical techniques to sediments from reclaimed and intact tidal marshes in southeast Australia. We aimed to assess the impacts of reclamation on: 1) the magnitude of existing sediment C stocks; 2) ongoing C sequestration and storage; and 3) C quality. Differences in sediment horizon depths (indicated by Itrax-XRF scanning) and ages (indicated by lead-210 and radiocarbon dating) suggest a physical loss of sediments following reclamation, as well as slowing of sediment accumulation rates. Sediments at one meter depth were between ~2000 and ~5300 years older in reclaimed cores compared to intact marsh cores. We estimate a 70% loss of sediment C in reclaimed sites (equal to 73 Mg C ha−1), relative to stocks in intact tidal marshes during a comparable time period. Following reclamation, sediment C was characterized by coarse particulate organic matter with lower alkyl-o-alkyl ratios and higher amounts of aromatic C, suggesting a lower extent of decomposition and therefore lower likelihood of being incorporated into long-term C stocks compared to that of intact tidal marshes. We conclude that reclamation of tidal marshes can diminish C stocks that have accumulated over millennial time scales, and these losses may go undetected if additional analyses are not employed in conjunction with C stock estimates. Unlabelled Image • Reclamation of tidal marshes resulted in a 70% loss of sediment carbon stocks. • Carbon stock losses caused by reclamation may go undetected without in-depth analysis. • "New" carbon in reclaimed sites was more degradable than in pristine tidal marshes. [ABSTRACT FROM AUTHOR]
- Published
- 2019
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36. Quantifying blue carbon stocks and the role of protected areas to conserve coastal wetlands.
- Author
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Duarte de Paula Costa, Micheli, Adame, Maria Fernanda, Bryant, Catherine V., Hill, Jack, Kelleway, Jeffrey J., Lovelock, Catherine E., Ola, Anne, Rasheed, Michael A., Salinas, Cristian, Serrano, Oscar, Waltham, Nathan, York, Paul H., Young, Mary, and Macreadie, Peter
- Published
- 2023
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- View/download PDF
37. Is demineralization with dilute hydrofluoric acid a viable method for isolating mineral stabilized soil organic matter?
- Author
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Sanderman, Jonathan, Farrell, Mark, McGowan, Janine, Baldock, Jeff, Macreadie, Peter I., and Hayes, Matthew
- Subjects
- *
HYDROFLUORIC acid , *HUMUS , *DEMINERALIZATION , *CARBON in soils , *SOIL mineralogy , *NUCLEAR magnetic resonance spectroscopy , *CARBON sequestration - Abstract
Hydrofluoric acid (HF) is a powerful tool in the investigation of soil organic matter (SOM) due to its ability to dissolve minerals but not break the chemical bonds of organic matter. These properties make the use of HF a common pretreatment step for removing paramagnetic interferences and concentrating carbon prior to solid-state 13 C NMR spectroscopy with the working assumption that any SOM lost during HF treatment will not bias the resulting NMR spectra. Hydrofluoric acid is also used to isolate a mineral-stabilized OM fraction with the working assumption that most mineral-stabilized OM is primarily low molecular weight compounds bound to mineral surfaces and when the minerals are dissolved in HF, the OM bound to these surfaces will be lost to solution. The working assumptions behind these two uses of HF dissolution appear to be contradictory. To address this apparent conundrum, we treated a number of simple organic compounds, soil and sediment samples with HF in 2 and 10% concentrations and tracked C and N loss as well as chemical shifts observed in solid-state 13 C NMR spectra. For the soil and sediment samples there were inconsistent C and N losses but no difference in loss between the 2% and 10% HF concentrations. There were no obvious soil properties that could explain the differences in C or N loss. Overall, there were significant shifts in NMR-observable organic chemistry after treatment with both 2 and 10% HF with anoxic fine grained sediments under a seagrass meadow exhibiting strong preferential loss of O-alkyl C while terrestrial soils generally lost OM with more of a mixed chemical character. For many samples, the degree of selective loss was enough to significantly bias the interpretation of OM composition. Given the lack of ability to explain the large differences in C loss between samples with observed soil properties, this study suggests that caution should be used when interpreting HF-soluble C to indicate a mineral-stabilized fraction without considering the soil physicochemical environment and putative mechanisms for organo-mineral associations in that particular soil. [ABSTRACT FROM AUTHOR]
- Published
- 2017
- Full Text
- View/download PDF
38. Blue carbon drawdown by restored mangrove forests improves with age.
- Author
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Carnell, Paul E., Palacios, Maria M., Waryszak, Paweł, Trevathan-Tackett, Stacey M., Masqué, Pere, and Macreadie, Peter I.
- Subjects
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MANGROVE plants , *MANGROVE forests , *FOREST restoration , *CARBON offsetting , *CARBON sequestration , *CARBON cycle , *CARBON , *CARBON in soils - Abstract
The restoration of blue carbon ecosystems, such as mangrove forests, is increasingly used as a management tool to mitigate climate change by removing and sequestering atmospheric carbon in the ground. However, estimates of carbon-offset potential are currently based on data from natural mangrove forests, potentially leading to overestimating the carbon-offset potential from restored mangroves. Here, in the first study of its kind, we utilise 210Pb sediment age-dating techniques and greenhouse gas flux measures to estimate blue carbon additionality in restored mangrove forests, ranging from 13 to 35 years old. As expected, mangrove age had a significant effect on carbon additionality and carbon accretion rate, with the older mangrove stands (17 and 35 years old) holding double the total carbon stocks (aboveground + soil stocks; ∼115 tonnes C ha−1) and double the soil sequestration rates (∼3 tonnes C ha−1 yr−1) than the youngest mangrove stand (13 years old). Although soil carbon stocks increased with mangrove age, the aboveground plant stocks were highest in the 17-year-old stand. Mangrove age also had a significant effect on soil carbon fluxes, with the older mangroves (≥17 years) releasing one-fourth of the CH 4 emissions, but double the CO 2 flux compared to young stands. Our study suggests that the carbon sink capacity of restored mangrove forests increases with age, but stabilises once they mature (e.g., >17 years). This means that by using carbon sequestration and emissions from natural forests, mangrove restoration projects may be overestimating their carbon sequestration potential. • Soil age-dating revealed the carbon sequestered by restored mangrove forests. • Older mangroves hold double the total carbon stocks (∼115 t C ha−1) than younger ones. • Older mangroves have double the sequestration (∼3 t C ha−1 yr−1) than younger ones. • Mangrove age is linked to low methane emissions, but high carbon dioxide fluxes. • Managers must include mangrove age when predicting carbon offsets from restoration. [ABSTRACT FROM AUTHOR]
- Published
- 2022
- Full Text
- View/download PDF
39. Modelling blue carbon farming opportunities at different spatial scales.
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Duarte de Paula Costa, Micheli, Lovelock, Catherine E., Waltham, Nathan J., Moritsch, Monica M., Butler, Don, Power, Trent, Thomas, Evan, and Macreadie, Peter I.
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MANGROVE plants , *SEAGRASS restoration , *SALT marshes , *CARBON sequestration , *CLIMATE change mitigation , *CARBON offsetting , *CARBON pricing - Abstract
There is a growing interest in including blue carbon ecosystems (i.e., mangroves, tidal marshes and seagrasses) in climate mitigation programs in national and sub-national policies, with restoration and conservation of these ecosystems identified as potential activities to increase carbon accumulation through time. However, there is still a gap on the spatial scales needed to produce carbon offsets comparable with terrestrial or agricultural ecosystems. Here, we used the Coastal Blue Carbon InVEST 3.7.0 model to estimate future net carbon sequestration in blue carbon ecosystems along Australia's Great Barrier Reef (hereafter GBR) catchments, considering different management scenarios (i.e., reintroduction of tidal exchange through the removal of barriers, sea level rise, restoring low lying land) at three different spatial scales: whole GBR coastline, regional (14,000–16,300 ha), and local (335–370 ha) scales. The focus of the restoration (i.e., tidal marshes and/or mangroves) was dependent on data availability for each scenario. Furthermore, we also estimated the monetary value of carbon sequestration under each management scenario and spatial scale assessed in the study. We found that large scale restoration of tidal marshes could potentially sequester an additional ∼800,000 tonnes of CO 2 e by 2045 (potentially generating AU$12 million based on the average Australia carbon price), with greater opportunities when sea level rise is accounted for in the modelling. Also, we found that regional and local projects would generate up to 23 tonnes CO 2 e ha−1 by the end of the crediting period. Our results can guide future decisions in the blue carbon market and financing schemes, however, the return on investment is dependent on the carbon price and funding scheme available for project implementation. • Blue carbon farming can help national climate mitigation efforts. • Spatially explicit maps of net carbon sequestration were developed for different management scenarios. • Large-scale restoration of tidal marshes could sequester an additional ∼800,000 tonnes of CO 2 e by 2045. • Future sea level rise could increase the opportunity to 2.2 million tonnes CO 2 e by 2045. • Regional and local projects could generate up to 23 tonnes CO 2 e ha−1 considering a crediting period of 25 years. [ABSTRACT FROM AUTHOR]
- Published
- 2022
- Full Text
- View/download PDF
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