Optimising reef-scale CO2 removal by seaweed to buffer ocean acidification

Optimising reef-scale CO2 removal by seaweed to buffer ocean acidification

The equilibration of rising atmospheric with the ocean is lowering in tropical waters by about 0.01 every decade. Coral reefs and the ecosystems they support are regarded as one of the most vulnerable ecosystems to ocean acidification, threatening their long-term viability. In response to this threa...

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Bibliographic Details
Published in:Environmental research letters Vol. 11; no. 3; pp. 034023 - 34032
Main Authors: Mongin, Mathieu, Baird, Mark E, Hadley, Scott, Lenton, Andrew
Format: Journal Article
Language:English
Published: Bristol IOP Publishing 16-03-2016
Subjects:
Acidification
Algae
Aragonite
Biomass
Buffers
Carbon
Carbon dioxide
Carbon sequestration
carbonate chemistry
coral reef
Coral reefs
Corals
Farms
Marine ecosystems
marine management
ocean acidfication
Ocean acidification
Optimization
pH effects
Seaweeds
Time dependence
Heron Island
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Summary:The equilibration of rising atmospheric with the ocean is lowering in tropical waters by about 0.01 every decade. Coral reefs and the ecosystems they support are regarded as one of the most vulnerable ecosystems to ocean acidification, threatening their long-term viability. In response to this threat, different strategies for buffering the impact of ocean acidification have been proposed. As the experienced by individual corals on a natural reef system depends on many processes over different time scales, the efficacy of these buffering strategies remains largely unknown. Here we assess the feasibility and potential efficacy of a reef-scale (a few kilometers) carbon removal strategy, through the addition of seaweed (fleshy multicellular algae) farms within the Great Barrier Reef at the Heron Island reef. First, using diagnostic time-dependent age tracers in a hydrodynamic model, we determine the optimal location and size of the seaweed farm. Secondly, we analytically calculate the optimal density of the seaweed and harvesting strategy, finding, for the seaweed growth parameters used, a biomass of 42 g N m−2 with a harvesting rate of up 3.2 g N m−2 d−1 maximises the carbon sequestration and removal. Numerical experiments show that an optimally located 1.9 km2 farm and optimally harvested seaweed (removing biomass above 42 g N m−2 every 7 d) increased aragonite saturation by 0.1 over 24 km2 of the Heron Island reef. Thus, the most effective seaweed farm can only delay the impacts of global ocean acidification at the reef scale by 7-21 years, depending on future global carbon emissions. Our results highlight that only a kilometer-scale farm can partially mitigate global ocean acidification for a particular reef.
Bibliography:ERL-101857.R2
ISSN:1748-9326
DOI:10.1088/1748-9326/11/3/034023