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Seaweed forests are an overlooked component of oceanic carbon storage

22 May 2024

A groundbreaking study by an international team of researchers, including scientists from Plymouth Marine Laboratory (PML), has revealed seaweed forests to be significant contributors to oceanic carbon storage.

Oleksandr Sushko | Unsplash

The research estimates that the world’s seaweed forests transport 56 million tonnes of carbon (between 10 to 170 million tonnes) to deep ocean sinks each year. Between 4 and 44 million tonnes of this carbon could remain sequestered in these deep sinks for at least a hundred years.

This discovery, published in the prestigious journal Nature Geoscience, highlights a considerable contribution of macroalgae to oceanic carbon sinks. The study also suggests that large-scale shifts in seaweed forest distribution and abundance, including past and ongoing losses, would affect the carbon sink capacity. The study thereby provides further impetus for efforts to increase seaweed forests through conservation or restorations.

Seaweed forests, primarily composed of large brown macroalgae like kelps and rockweeds, are among the most extensive and productive vegetated coastal ecosystem on the planet and are hotspots of marine biodiversity. These ocean forests can grow as rapidly as forests on land and are efficient in capturing carbon, which they store in their biomass. Part of this biomass can be transported to deep ocean sinks.

The research, spearheaded by Dr Karen Filbee-Dexter at the Norwegian Institute of Marine Research and the University of Western Australia, reveals that seaweed forests export about 15% of their captured carbon into deep ocean waters each year, where part of it can remain trapped for centuries.

The study estimates that seaweed-carbon export below 200 m depth totalled 3-4% of the ocean carbon sink. The findings thereby underscore the need to include macroalgae in the depictions of the global ocean carbon budget, which still ignores the contribution of marine vegetation.

The international team used state-of-the-art global ocean models to track the fate of seaweed carbon from the coast to the deep ocean. The transport time for macroalgae to the deep ocean was compared to their degradation rate to estimate the fraction that would reach the deep sinks.

The team then identified hotspots of carbon export globally, for example, in areas with extensive seaweed forests or coastal areas with canyons or narrow continental shelves that are close to the deep sea.

“The study also identified the seaweed forests of Australia, the USA, New Zealand, Indonesia and Chile as having high carbon removal capacity” said Dr. Filbee-Dexter.

The coastal ocean represents an important global carbon sink and is a focus for interventions to mitigate climate change and meet the Paris Agreement targets while supporting biodiversity.

Dr Pessarrodona, a co-author of the study, said this research is relevant to conservation, because when seaweed forests are lost, and e.g. replaced by sea urchins, this drawdown of carbon stops. The study underscores the urgent need to act more quickly to protect, manage and restore seaweed forests, which are being lost at alarming rates in many regions of the world due to a variety of human pressures such as ocean warming, marine heatwaves, nutrient pollution, and overfishing.

The conservation and restoration of seaweed forests not only helps in atmospheric carbon removal, but also enhances biodiversity and supports fisheries, making them an invaluable resource for combating climate change and preserving biodiversity in our oceans” said Dr. Pessarrodona.

Prof. Ana Queirós, co-author on the study and Marine and Climate Change Ecologist at Plymouth Marine Laboratory, said:

“Identifying seaweed forests and promoting their management will help us capitalise on natural solutions to the carbon challenge, and work towards the stabilisation of the global climate system. This work not only highlights that these important habitats need protective management but also will help refine the carbon estimates in Earth system models. The next step is to consider where seaweed detritus, and therefore the carbon locked within, may be deposited to gain a fuller picture of the ocean carbon cycle”.

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