Journal ArticleDOI
Surface evolution and carbon sequestration in disturbed and undisturbed wetland soils of the Hunter estuary, southeast Australia
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In this article, the authors quantify the soil carbon storage and sequestration rates of undisturbed natural wetlands and disturbed wetlands subject to restriction of tidal flow and subsequent rehabilitation in an Australian estuary.Abstract:
The aim of this work was to quantify the soil carbon storage and sequestration rates of undisturbed natural wetlands and disturbed wetlands subject to restriction of tidal flow and subsequent rehabilitation in an Australian estuary. Disturbed and undisturbed estuarine wetlands of the Hunter estuary, New South Wales, Australia were selected as the study sites for this research. Vertical accretion rates of estuarine substrates were combined with soil carbon concentrations and bulk densities to determine the carbon store and carbon sequestration rates of the substrates tested. Relationships between estuary water level, soil evolution and vertical accretion were also examined. The carbon sequestration rate of undisturbed wetlands was lower (15% for mangrove and 55% for saltmarsh) than disturbed wetlands, but the carbon store was higher (65% for mangrove and 60% for saltmarsh). The increased carbon sequestration rate of the disturbed wetlands was driven by substantially higher rates of vertical accretion (95% for mangrove and 345% for saltmarsh). Estuarine wetland carbon stores were estimated at 700–1000 Gg C for the Hunter estuary and 3900–5600 Gg C for New South Wales. Vertical accretion and carbon sequestration rates of estuarine wetlands in the Hunter are at the lower end of the range reported in the literature. The comparatively high carbon sequestration rates reported for the disturbed wetlands in this study indicate that wetland rehabilitation has positive benefits for regulation of atmospheric carbon concentrations, in addition to more broadly accepted ecosystem services.read more
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Journal ArticleDOI
Wetlands, carbon, and climate change
William J. Mitsch,William J. Mitsch,Blanca Bernal,Amanda M. Nahlik,Amanda M. Nahlik,Ülo Mander,Li Zhang,Li Zhang,Christopher J. Anderson,Christopher J. Anderson,Sven Erik Jørgensen,Hans Brix +11 more
TL;DR: In this article, the authors show that most wetlands, when compared to methane emissions, do not have 25 times more CO2 sequestration than methane emissions; therefore, to many landscape managers and non specialists, most wetlands would be considered by some to be sources of climate warming or net radiative forcing.
Journal ArticleDOI
Mangrove expansion and salt marsh decline at mangrove poleward limits
TL;DR: There is now sufficient evidence that mangrove species have proliferated at or near their poleward limits on at least five continents over the past half century, at the expense of salt marsh, consistent with the poleward extension of temperature thresholds coincident with sea-level rise.
Journal ArticleDOI
The future of Blue Carbon science
Peter I. Macreadie,Andrea Anton,John A. Raven,John A. Raven,John A. Raven,Nicola Beaumont,Rod M. Connolly,Daniel A. Friess,Jeffrey J. Kelleway,Hilary Kennedy,Tomohiro Kuwae,Paul S. Lavery,Catherine E. Lovelock,Dan A. Smale,Eugenia T. Apostolaki,Trisha B. Atwood,Jeff Baldock,Thomas S. Bianchi,Gail L. Chmura,Bradley D. Eyre,James W. Fourqurean,James W. Fourqurean,Jason M. Hall-Spencer,Jason M. Hall-Spencer,Mark Huxham,Iris E. Hendriks,Dorte Krause-Jensen,Dan Laffoley,Tiziana Luisetti,Núria Marbà,Pere Masqué,Pere Masqué,Pere Masqué,Karen J. McGlathery,J. Patrick Megonigal,Daniel Murdiyarso,Daniel Murdiyarso,Bayden D. Russell,Rui Santos,Oscar Serrano,Brian R. Silliman,Kenta Watanabe,Carlos M. Duarte +42 more
TL;DR: The authors identify the top-ten unresolved questions in the field and find that most questions relate to the precise role blue carbon can play in mitigating climate change and the most effective management actions in maximising this.
Journal ArticleDOI
Updated estimates of carbon accumulation rates in coastal marsh sediments
Xiaoguang Ouyang,Shing Yip Lee +1 more
TL;DR: In this article, the authors present an updated estimate of the global average carbon ac- cumulation rate (CAR) at 244.7 g C m 2 yr 1 in salt marsh sediments, based on region-specific CAR and estimates of salt marsh area in various geographic regions between 40 S to 69.7 N.
Journal ArticleDOI
A global standard for monitoring coastal wetland vulnerability to accelerated sea-level rise
Edward L. Webb,Daniel A. Friess,Ken W. Krauss,Donald R. Cahoon,Glenn R. Guntenspergen,Jacob Phelps +5 more
TL;DR: In this paper, a simple, inexpensive and low-technology device called the "rod surface elevation table" could be used to monitor threatened coastal wetlands around the world, which is used to predict the probable impact of sea-level rise on vulnerable coastal ecosystems and for science-informed management, adaptation and mitigation.
References
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Journal ArticleDOI
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