Quantifying blue carbon and nitrogen stocks in surface soils of temperate coastal wetlands
Christina H. Asanopoulos A B C , Jeff A. Baldock A B , Lynne M. Macdonald A B and Timothy R. Cavagnaro AA The Waite Research Institute and School of Agriculture, Food and Wine, The University of Adelaide, PMB 1 Glen Osmond, SA 5064, Australia.
B CSIRO Agriculture & Food, PMB 2 Glen Osmond, SA 5064, Australia.
C Corresponding author. Email: christina.asanopoulos@csiro.au
Soil Research - https://doi.org/10.1071/SR20040
Submitted: 11 February 2020 Accepted: 22 April 2021 Published online: 25 June 2021
Journal Compilation © CSIRO 2021 Open Access CC BY-NC
Abstract
Coastal wetlands are carbon and nutrient sinks that capture large amounts of atmospheric CO2 and runoff of nutrients. ‘Blue carbon’ refers to carbon stored within resident vegetation (e.g. mangroves, tidal marshes and seagrasses) and soil of coastal wetlands. This study aimed to quantify the impact of vegetation type on soil carbon stocks (organic and inorganic) and nitrogen in the surface soils (0–10 cm) of mangroves and tidal marsh habitats within nine temperate coastal blue carbon wetlands in South Australia. Results showed differences in surface soil organic carbon stocks (18.4 Mg OC ha–1 for mangroves; 17.6 Mg OC ha–1 for tidal marshes), inorganic carbon (31.9 Mg IC ha–1 for mangroves; 35.1 Mg IC ha–1 for tidal marshes), and total nitrogen (1.8 Mg TN ha–1 for both) were not consistently driven by vegetation type. However, mangrove soils at two sites (Clinton and Port Augusta) and tidal marsh soils at one site (Torrens Island) had larger soil organic carbon (SOC) stocks. These results highlighted site-specific differences in blue carbon stocks between the vegetation types and spatial variability within sites. Further, differences in spatial distribution of SOC within sites corresponded with variations in soil bulk density (BD). Results highlighted a link between SOC and BD in blue carbon soils. Understanding the drivers of carbon and nitrogen storage across different blue carbon environments and capturing its spatial variability will help improve predictions of the contribution these ecosystems to climate change mitigation.
Keywords: blue carbon, coastal wetlands, mangroves, soil carbon, soil nitrogen, temperate wetlands, tidal marshes.
References
Adame MF, Santini NS, Tovilla C, Vazquez-Lule A, Castro L, Guevara M (2015) Carbon stocks and soil sequestration rates of tropical riverine wetlands. Biogeosciences 12, 3805–3818.| Carbon stocks and soil sequestration rates of tropical riverine wetlands.Crossref | GoogleScholarGoogle Scholar |
Alongi DM (2002) Present state and future of the world’s mangrove forests. Environmental Conservation 29, 331–349.
| Present state and future of the world’s mangrove forests.Crossref | GoogleScholarGoogle Scholar |
Atwood TB, Connolly RM, Almahasheer H, Carnell PE, Duarte CM, Ewers Lewis CJ, Irigoien X, Kelleway JJ, Lavery PS, Macreadie PI, Serrano O, Sanders CJ, Santos I, Steven ADL, Lovelock CE (2017) Global patterns in mangrove soil carbon stocks and losses. Nature Climate Change 7, 523–528.
| Global patterns in mangrove soil carbon stocks and losses.Crossref | GoogleScholarGoogle Scholar |
Auguie B (2016) gridExtra: Miscellaneous Functions for “Grid” Graphics. R package version 2.2.1. URL https://CRAN.R-project.org/package=gridExtra
Baker, JL (2015) Marine Assets of Yorke Peninsula. Volume 2 of report for Natural Resources - Northern and Yorke, South Australia. Available at https://www.naturalresources.sa.gov.au/files/sharedassets/northern_and_yorke/coast_and_marine/yp_2014_assets_-_part_2_-_marine_ecological_assets_-_section_151_-_rock_islands.pdf
Baldock JA, Sanderman J, Macdonald LM, Puccini A, Hawke B, Szarvas S, McGowan J (2013) Quantifying the allocation of soil organic carbon to biologically significant fractions. Soil Research 51, 561–576.
| Quantifying the allocation of soil organic carbon to biologically significant fractions.Crossref | GoogleScholarGoogle Scholar |
Bates D, Maechler M, Bolker B, Walker S (2015) Fitting Linear Mixed-Effects Models Using lme4. Journal of Statistical Software 67, 1–48.
| Fitting Linear Mixed-Effects Models Using lme4.Crossref | GoogleScholarGoogle Scholar |
Bouillon S, Dahdouh-Guebas F, Rao AVVS, Koedam N, Dehairs F (2003) Sources of organic carbon in mangrove sediments: variability and possible ecological implications. Hydrobiologia 495, 33–39.
| Sources of organic carbon in mangrove sediments: variability and possible ecological implications.Crossref | GoogleScholarGoogle Scholar |
Bouillon S, Borges AV, Castañeda‐Moya E, Diele K, Dittmar T, Duke NC, Kristensen E, Lee SY, Marchand C, Middelburg JJ, Rivera‐Monroy VH, Smith TJ, Twilley RR (2008) Mangrove production and carbon sinks: A revision of global budget estimates. Global Biogeochemical Cycles 22,
| Mangrove production and carbon sinks: A revision of global budget estimates.Crossref | GoogleScholarGoogle Scholar |
Bourman RP, Murray-Wallace C, Harvey N (2016) 'Coastal Landscapes of South Australia.' (University of Adelaide Press: Adelaide)
Breithaupt JL, Smoak JM, Smith TJ, Sanders CJ (2014) Temporal variability of carbon and nutrient burial, sediment accretion, and mass accumulation over the past century in a carbonate platform mangrove forest of the Florida Everglades. Journal of Geophysical Research. Biogeosciences 119, 2032–2048.
| Temporal variability of carbon and nutrient burial, sediment accretion, and mass accumulation over the past century in a carbonate platform mangrove forest of the Florida Everglades.Crossref | GoogleScholarGoogle Scholar |
Breithaupt JL, Smoak JM, Rivera-Monroy VH, Castañeda-Moya E, Moyer RP, Simard M, Sanders CJ (2017) Partitioning the relative contributions of organic matter and mineral sediment to accretion rates in carbonate platform mangrove soils. Marine Geology 390, 170–180.
| Partitioning the relative contributions of organic matter and mineral sediment to accretion rates in carbonate platform mangrove soils.Crossref | GoogleScholarGoogle Scholar |
Breithaupt JL, Smoak JM, Sanders CJ, Troxler TG (2019) Spatial Variability of Organic Carbon, CaCO3 and Nutrient Burial Rates Spanning a Mangrove Productivity Gradient in the Coastal Everglades. Ecosystems 22, 844–858.
| Spatial Variability of Organic Carbon, CaCO3 and Nutrient Burial Rates Spanning a Mangrove Productivity Gradient in the Coastal Everglades.Crossref | GoogleScholarGoogle Scholar |
Chmura GL, Anisfeld SC, Cahoon DR, Lynch JC (2003) Global carbon sequestration in tidal, saline wetland soils. Global Biogeochemical Cycles 17,
| Global carbon sequestration in tidal, saline wetland soils.Crossref | GoogleScholarGoogle Scholar |
Donato DC, Kauffman JB, Murdiyarso D, Kurnianto S, Stidham M, Kanninen M (2011) Mangroves among the most carbon-rich forests in the tropics. Nature Geoscience 4, 293–297.
| Mangroves among the most carbon-rich forests in the tropics.Crossref | GoogleScholarGoogle Scholar |
Duarte CM, Losada IJ, Hendriks IE, Mazarrasa I, Marbà N (2013) The role of coastal plant communities for climate change mitigation and adaptation. Nature Climate Change 3, 961–968.
| The role of coastal plant communities for climate change mitigation and adaptation.Crossref | GoogleScholarGoogle Scholar |
Edyvane KS (1999) Coastal and marine wetlands in Gulf St. Vincent, South Australia: understanding their loss and degradation Wetlands Ecology and Management 7, 83–104.
| Coastal and marine wetlands in Gulf St. Vincent, South Australia: understanding their loss and degradationCrossref | GoogleScholarGoogle Scholar |
EPA (2021) Investigation into dieback of St Kilda mangroves. Available at https://www.epa.sa.gov.au/articles/2020/12/18/investigation_into_dieback_of_st_kilda_mangroves
Ewers Lewis CJ, Carnell PE, Sanderman J, Baldock JA, Macreadie PI (2018) Variability and Vulnerability of Coastal ‘Blue Carbon’ Stocks: A Case Study from Southeast Australia. Ecosystems 21, 263–279.
| Variability and Vulnerability of Coastal ‘Blue Carbon’ Stocks: A Case Study from Southeast Australia.Crossref | GoogleScholarGoogle Scholar |
Ewers Lewis CJ, Young MA, Ierodiaconou D, Baldock JA, Hawke B, Sanderman J, Carnell PE, Macreadie PI (2020) Drivers and modelling of blue carbon stock variability in sediments of southeastern Australia. Biogeosciences 17, 2041–2059.
| Drivers and modelling of blue carbon stock variability in sediments of southeastern Australia.Crossref | GoogleScholarGoogle Scholar |
Feher LC, Osland MJ, Griffith KT, Grace JB, Howard RJ, Stagg CL, Enwright NM, Krauss KW, Gabler CA, Day RH, Rogers K (2017) Linear and nonlinear effects of temperature and precipitation on ecosystem properties in tidal saline wetlands. Ecosphere 8, e01956
| Linear and nonlinear effects of temperature and precipitation on ecosystem properties in tidal saline wetlands.Crossref | GoogleScholarGoogle Scholar |
Foster N, Jones AR, Waycott M, Gillanders BM (2019) Coastal carbon opportunities: technical report on changes in the distribution of mangrove and saltmarsh across South Australia (1987–2015). Goyder Institute for Water Research Technical Report. Available at http://www.goyderinstitute.org/_r2158/media/system/attrib/file/602/Goyder_TRS-19-23%20Coastal%20C%20Task2a_technical%20report_Final.pdf
Hayes MA, Jesse A, Hawke B, Baldock J, Tabet B, Lockington D, Lovelock CE (2017) Dynamics of sediment carbon stocks across intertidal wetland habitats of Moreton Bay, Australia. Global Change Biology 23, 4222–4234.
| Dynamics of sediment carbon stocks across intertidal wetland habitats of Moreton Bay, Australia.Crossref | GoogleScholarGoogle Scholar | 28407457PubMed |
Heuscher SA, Brandt CC, Jardine PM (2005) Using Soil Physical and Chemical Properties to Estimate Bulk Density. Soil Science Society of America Journal 69, 51–56.
| Using Soil Physical and Chemical Properties to Estimate Bulk Density.Crossref | GoogleScholarGoogle Scholar |
Howard J, Sutton-Grier A, Herr D, Kleypas J, Landis E, Mcleod E, Pidgeon E, Simpson S (2017) Clarifying the role of coastal and marine systems in climate mitigation. Frontiers in Ecology and the Environment 15, 42–50.
| Clarifying the role of coastal and marine systems in climate mitigation.Crossref | GoogleScholarGoogle Scholar |
Howe AJ, Rodríguez JF, Saco PM (2009) Surface evolution and carbon sequestration in disturbed and undisturbed wetland soils of the Hunter estuary, southeast Australia. Estuarine, Coastal and Shelf Science 84, 75–83.
| Surface evolution and carbon sequestration in disturbed and undisturbed wetland soils of the Hunter estuary, southeast Australia.Crossref | GoogleScholarGoogle Scholar |
International VSN (2017) ‘Genstat for Windows 19th Edition.’ Hemel Hempstead, UK.)
Kauffman JB, Heider C, Cole TG, Dwire KA, Donato DC (2011) Ecosystem Carbon Stocks of Micronesian Mangrove Forests. Wetlands 31, 343–352.
| Ecosystem Carbon Stocks of Micronesian Mangrove Forests.Crossref | GoogleScholarGoogle Scholar |
Kelleway JJ, Saintilan N, Macreadie PI, Ralph PJ (2016a) Sedimentary Factors are Key Predictors of Carbon Storage in SE Australian Saltmarshes. Ecosystems 19, 865–880.
| Sedimentary Factors are Key Predictors of Carbon Storage in SE Australian Saltmarshes.Crossref | GoogleScholarGoogle Scholar |
Kelleway JJ, Saintilan N, Macreadie PI, Skilbeck CG, Zawadzki A, Ralph PJ (2016b) Seventy years of continuous encroachment substantially increases ‘blue carbon’ capacity as mangroves replace intertidal salt marshes. Global Change Biology 22, 1097–1109.
| Seventy years of continuous encroachment substantially increases ‘blue carbon’ capacity as mangroves replace intertidal salt marshes.Crossref | GoogleScholarGoogle Scholar | 26670941PubMed |
Kelleway JJ, Saintilan N, Macreadie PI, Baldock JA, Ralph PJ (2017a) Sediment and carbon deposition vary among vegetation assemblages in a coastal salt marsh. Biogeosciences 14, 3763–3779.
| Sediment and carbon deposition vary among vegetation assemblages in a coastal salt marsh.Crossref | GoogleScholarGoogle Scholar |
Kelleway JJ, Saintilan N, Macreadie PI, Baldock JA, Heijnis H, Zawadzki A, Gadd P, Jacobsen G, Ralph PJ (2017b) Geochemical analyses reveal the importance of environmental history for blue carbon sequestration. Journal of Geophysical Research. Biogeosciences 122, 1789–1805.
| Geochemical analyses reveal the importance of environmental history for blue carbon sequestration.Crossref | GoogleScholarGoogle Scholar |
Lamb AL, Wilson GP, Leng MJ (2006) A review of coastal palaeoclimate and relative sea-level reconstructions using δ13C and C/N ratios in organic material. Earth-Science Reviews 75, 29–57.
| A review of coastal palaeoclimate and relative sea-level reconstructions using δ13C and C/N ratios in organic material.Crossref | GoogleScholarGoogle Scholar |
Lavery PS, Lafratta A, Serrano O, Masqué P, Jones A, Fernandes M, Gaylard S, Gillanders B (2019) Coastal carbon opportunities: technical report on carbon storage and accumulation rates at three case study sites. Goyder Institute for Water Research Technical Report Series No. 19/21. Available.
Livesley SJ, Andrusiak SM (2012) Temperate mangrove and salt marsh sediments are a small methane and nitrous oxide source but important carbon store. Estuarine, Coastal and Shelf Science 97, 19–27.
| Temperate mangrove and salt marsh sediments are a small methane and nitrous oxide source but important carbon store.Crossref | GoogleScholarGoogle Scholar |
Lovelock CE, Feller IC, Ellis J, Schwarz AM, Hancock N, Nichols P, Sorrell B (2007) Mangrove growth in New Zealand estuaries: the role of nutrient enrichment at sites with contrasting rates of sedimentation. Oecologia 153, 633–641.
| Mangrove growth in New Zealand estuaries: the role of nutrient enrichment at sites with contrasting rates of sedimentation.Crossref | GoogleScholarGoogle Scholar | 17492316PubMed |
Lovelock CE, Adame MF, Bennion V, Hayes M, O’Mara J, Reef R, Santini NS (2014) Contemporary Rates of Carbon Sequestration Through Vertical Accretion of Sediments in Mangrove Forests and Saltmarshes of South East Queensland, Australia. Estuaries and Coasts 37, 763–771.
| Contemporary Rates of Carbon Sequestration Through Vertical Accretion of Sediments in Mangrove Forests and Saltmarshes of South East Queensland, Australia.Crossref | GoogleScholarGoogle Scholar |
Macreadie PI, Serrano O, Maher DT, Duarte CM, Beardall J (2017) Addressing calcium carbonate cycling in blue carbon accounting. Limnology and Oceanography Letters 2, 195–201.
| Addressing calcium carbonate cycling in blue carbon accounting.Crossref | GoogleScholarGoogle Scholar |
Mitra A, Zaman S (2014) ‘Carbon Sequestration by Coastal Floral Community.’ (TERI: New Delhi)
Moseman-Valtierra S, Gonzalez R, Kroeger KD, Tang J, Chao WC, Crusius J, Bratton J, Green A, Shelton J (2011) Short-term nitrogen additions can shift a coastal wetland from a sink to a source of N2O. Atmospheric Environment 45, 4390–4397.
| Short-term nitrogen additions can shift a coastal wetland from a sink to a source of N2O.Crossref | GoogleScholarGoogle Scholar |
Owers CJ, Rogers K, Mazumder D, Woodroffe CD (2016a) Spatial Variation in Carbon Storage: A Case Study for Currambene Creek, NSW, Australia. Journal of Coastal Research 75, 1297–1301.
| Spatial Variation in Carbon Storage: A Case Study for Currambene Creek, NSW, Australia.Crossref | GoogleScholarGoogle Scholar |
Owers CJ, Rogers K, Woodroffe CD (2016b) Identifying spatial variability and complexity in wetland vegetation using an object-based approach. International Journal of Remote Sensing 37, 4296–4316.
| Identifying spatial variability and complexity in wetland vegetation using an object-based approach.Crossref | GoogleScholarGoogle Scholar |
Owers CJ, Rogers K, Mazumder D, Woodroffe CD (2020) Temperate coastal wetland near-surface carbon storage: Spatial patterns and variability. Estuarine, Coastal and Shelf Science 235, 106584
| Temperate coastal wetland near-surface carbon storage: Spatial patterns and variability.Crossref | GoogleScholarGoogle Scholar |
R Core Team (2017) ‘R: A language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria. URL https://www.R-project.org/
Reddy KR, DeLaune RD (2008) ‘Biogeochemistry of Wetlands: Science and Applications’ (CRC Press: Boca Raton)
RStudio Team (2016) ‘RStudio: Integrated Development for R. RStudio, Inc., Boston, MA URL http://www.rstudio.com/
Ruehlmann J, Körschens M (2009) Calculating the Effect of Soil Organic Matter Concentration on Soil Bulk Density. Soil Science Society of America Journal 73, 876–885.
| Calculating the Effect of Soil Organic Matter Concentration on Soil Bulk Density.Crossref | GoogleScholarGoogle Scholar |
Saderne V, Geraldi NR, Macreadie PI, Maher DT, Middelburg JJ, Serrano O, Almahasheer H, Arias-Ortiz A, Cusack M, Eyre BD, Fourqurean JW, Kennedy H, Krause-Jensen D, Kuwae T, Lavery PS, Lovelock CE, Marba N, Masqué P, Mateo MA, Mazarrasa I, McGlathery KJ, Oreska MPJ, Sanders CJ, Santos IR, Smoak JM, Tanaya T, Watanabe K, Duarte CM (2019) Role of carbonate burial in Blue Carbon budgets. Nature Communications 10, 1106
| Role of carbonate burial in Blue Carbon budgets.Crossref | GoogleScholarGoogle Scholar | 30846688PubMed |
Saderne V, Cusack M, Serrano O, Almahasheer H, Krishnakumar PK, Rabaoui L, Qurban MA, Duarte CM (2020) Role of vegetated coastal ecosystems as nitrogen and phosphorous filters and sinks in the coasts of Saudi Arabia. Environmental Research Letters 15, 034058
| Role of vegetated coastal ecosystems as nitrogen and phosphorous filters and sinks in the coasts of Saudi Arabia.Crossref | GoogleScholarGoogle Scholar |
Saintilan N, Rogers K, Mazumder D, Woodroffe C (2013) Allochthonous and autochthonous contributions to carbon accumulation and carbon store in southeastern Australian coastal wetlands. Estuarine, Coastal and Shelf Science 128, 84–92.
| Allochthonous and autochthonous contributions to carbon accumulation and carbon store in southeastern Australian coastal wetlands.Crossref | GoogleScholarGoogle Scholar |
Sanders CJ, Eyre BD, Santos IR, Machado W, Luiz-Silva W, Smoak JM, Breithaupt JL, Ketterer ME, Sanders L, Marotta H, Silva-Filho E (2014) Elevated rates of organic carbon, nitrogen, and phosphorus accumulation in a highly impacted mangrove wetland. Geophysical Research Letters 41, 2475–2480.
| Elevated rates of organic carbon, nitrogen, and phosphorus accumulation in a highly impacted mangrove wetland.Crossref | GoogleScholarGoogle Scholar |
Sanders CJ, Maher DT, Tait DR, Williams D, Holloway C, Sippo JZ, Santos IR (2016) Are global mangrove carbon stocks driven by rainfall? Journal of Geophysical Research. Biogeosciences 121, 2600–2609.
| Are global mangrove carbon stocks driven by rainfall?Crossref | GoogleScholarGoogle Scholar |
Siikamäki J, Sanchirico JN, Jardine S, McLaughlin D, Morris D (2013) Blue Carbon: Coastal Ecosystems, Their Carbon Storage, and Potential for Reducing Emissions. Environment 55, 14–29.
| Blue Carbon: Coastal Ecosystems, Their Carbon Storage, and Potential for Reducing Emissions.Crossref | GoogleScholarGoogle Scholar |
Turner ER, Milan CS, Swenson EM (2006) Recent volumetric changes in salt marsh soils. Estuarine, Coastal and Shelf Science 69, 352–359.
| Recent volumetric changes in salt marsh soils.Crossref | GoogleScholarGoogle Scholar |
Twilley RR, Chen RH, Hargis T (1992) Carbon sinks in mangroves and their implications to carbon budget of tropical coastal ecosystems. Water, Air, and Soil Pollution 64, 265–288.
| Carbon sinks in mangroves and their implications to carbon budget of tropical coastal ecosystems.Crossref | GoogleScholarGoogle Scholar |
Vohland M, Ludwig M, Sören T-B, Ludwig B (2014) Determination of Soil Properties with Visible to Near- and Mid-Infrared Spectroscopy: Effects of Spectral Variable Selection. Geoderma 223–225, 88–96.
| Determination of Soil Properties with Visible to Near- and Mid-Infrared Spectroscopy: Effects of Spectral Variable Selection.Crossref | GoogleScholarGoogle Scholar |
Wickham, H (2016) ggplot2: Elegant Graphics for Data Analysis. Springer-Verlag New York.
Yando ES, Osland MJ, Willis JM, Day RH, Krauss KW, Hester MW (2016) Salt marsh-mangrove ecotones: using structural gradients to investigate the effects of woody plant encroachment on plant–soil interactions and ecosystem carbon pools. Journal of Ecology 104, 1020–1031.
| Salt marsh-mangrove ecotones: using structural gradients to investigate the effects of woody plant encroachment on plant–soil interactions and ecosystem carbon pools.Crossref | GoogleScholarGoogle Scholar |