Seaweed afforestation at large-scales exclusively for carbon sequestration: Critical assessment of risks, viability and the state of knowledge

Ross, Finnley; Tarbuck, Patrick; Macreadie, Peter I.

doi:10.3389/fmars.2022.1015612

Cited by 16 publications

(25 citation statements)

References 137 publications

(175 reference statements)

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“…33 Seaweed is able to act as a carbon-neutral material by absorbing CO 2 from the atmosphere during photosynthesis, whereby CO 2 produced as emissions can be mitigated. 34 A range of methods have been explored to dewater and ultimately dry the seaweed feedstock: osmotic media, organic/mineral acids, screw-pressing, and conventional drying. 35 As seen in other research studies using seaweed towards biorefinery applications, these processes are species-dependent.…”

Section: Screening Of Seaweed Suitability Via Compositional Analysis ...mentioning

confidence: 99%

The Sea's best kept secret: the use of seaweed as a source of biohydrogen for clean and renewable energy

Wyper,

Zendehboudi,

Kerton

2024

RSC Sustain.

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Section: Screening Of Seaweed Suitability Via Compositional Analysis ...mentioning

confidence: 99%

The Sea's best kept secret: the use of seaweed as a source of biohydrogen for clean and renewable energy

Wyper,

Zendehboudi,

Kerton

2024

RSC Sustain.

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“…We focus on wild macroalgal ecosystems and intentionally refrain from contextualising these topics in relation to macroalgae farming. This focus arises because interventions around wild ecosystems presently have substantially higher potential abatement (NASEM, 2021), present more co-benefits (Forbes et al, 2022), and the CO 2removal capacity of macroalgae farming has been explored elsewhere (Arzeno-Soltero et al, 2023;Ross et al, 2022;Wu, Keller & Oschlies, 2023). Specifically, our review is largely centered on macroalgal forests formed by large brown algae (sensu Wernberg & Filbee-Dexter, 2019), which draw the greatest atmospheric CO 2 flux of any macroalgae habitat (Duarte et al, 2022;Pessarrodona et al, 2022) and whose contribution to sequestration is presumably the largest (Krause-Jensen & .…”

Section: Introductionmentioning

confidence: 99%

“…The need to ascertain new ocean‐based pathways to mitigate the effects of climate change has recently prompted revisiting of the role of macroalgae as an actionable blue carbon ecosystem (Macreadie et al ., 2019, 2021), including farmed macroalgae (Duarte et al ., 2017; Sondak et al ., 2017; Froehlich et al ., 2019). This in turn has attracted interest from a wide range of actors in government and private industry sectors (Coleman et al ., 2022; Friess et al ., 2022; Kuwae et al ., 2022 a ; Ross, Tarbuck & Macreadie, 2022), catalysing research and debate about their use as a climate mitigation tool.…”

Section: Introductionmentioning

confidence: 99%

Carbon sequestration and climate change mitigation using macroalgae: a state of knowledge review

et al. 2023

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The conservation, restoration, and improved management of terrestrial forests significantly contributes to mitigate climate change and its impacts, as well as providing numerous co‐benefits. The pressing need to reduce emissions and increase carbon removal from the atmosphere is now also leading to the development of natural climate solutions in the ocean. Interest in the carbon sequestration potential of underwater macroalgal forests is growing rapidly among policy, conservation, and corporate sectors. Yet, our understanding of whether carbon sequestration from macroalgal forests can lead to tangible climate change mitigation remains severely limited, hampering their inclusion in international policy or carbon finance frameworks. Here, we examine the results of over 180 publications to synthesise evidence regarding macroalgal forest carbon sequestration potential. We show that research efforts on macroalgae carbon sequestration are heavily skewed towards particulate organic carbon (POC) pathways (77% of data publications), and that carbon fixation is the most studied flux (55%). Fluxes leading directly to carbon sequestration (e.g. carbon export or burial in marine sediments) remain poorly resolved, likely hindering regional or country‐level assessments of carbon sequestration potential, which are only available from 17 of the 150 countries where macroalgal forests occur. To solve this issue, we present a framework to categorize coastlines according to their carbon sequestration potential. Finally, we review the multiple avenues through which this sequestration can translate into climate change mitigation capacity, which largely depends on whether management interventions can increase carbon removal above a natural baseline or avoid further carbon emissions. We find that conservation, restoration and afforestation interventions on macroalgal forests can potentially lead to carbon removal in the order of 10's of Tg C globally. Although this is lower than current estimates of natural sequestration value of all macroalgal habitats (61–268 Tg C year−1), it suggests that macroalgal forests could add to the total mitigation potential of coastal blue carbon ecosystems, and offer valuable mitigation opportunities in polar and temperate areas where blue carbon mitigation is currently low. Operationalizing that potential will necessitate the development of models that reliably estimate the proportion of production sequestered, improvements in macroalgae carbon fingerprinting techniques, and a rethinking of carbon accounting methodologies. The ocean provides major opportunities to mitigate and adapt to climate change, and the largest coastal vegetated habitat on Earth should not be ignored simply because it does not fit into existing frameworks.

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“…Seaweeds play an essential role in coastal ecosystems, such as the provision of food, a spatial refuge against predators and the cycling of nutrients (Teagle et al 2017; Gao et al 2021 a ). In addition, the huge potential of seaweeds to sequester carbon is attracting increasing global attention as the need for climate mitigation techniques grows more acute (Gao et al 2022; Ross et al 2022). Climate change is expected to impact seaweed carbon fixation and export (Wada et al 2021).…”

mentioning

confidence: 99%

“…In addition, the huge potential of seaweeds to sequester carbon is attracting increasing global attention as the need for climate mitigation techniques grows more acute (Gao et al 2022;Ross et al 2022). Climate change is expected to impact seaweed carbon fixation and export (Wada et al 2021).…”

mentioning

confidence: 99%

Nitrogen availability regulates the effects of a simulated marine heatwave on carbon sequestration and phycosphere bacteria of a marine crop

Jiang,

Hall‐Spencer,

Gao

et al. 2023

Limnology & Oceanography

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Great hope has been pinned on seaweed cultivation as being a potent way of removing CO2 to reduce rates of sea surface warming and acidification. Marine heatwaves and nitrogen pollution in coastal ecosystems are serious current issues that need to be better understood to inform decision making and policy. Here, we investigated the effects of a simulated heatwave and nitrogen pollution on carbon sequestration by an important seaweed crop species and its phycosphere bacteria. Gracilaria lemaneiformis was grown in ambient and high nitrogen conditions (14 and 200 μM L−1). Photosynthetic rate, seaweed biomass and particulate organic carbon accumulation were significantly increased in “high nitrogen‐no heatwave” conditions. In “ambient nitrogen heatwave” conditions, the expression of genes related to photosynthesis was down regulated and the seaweeds lost more dissolved organic carbon (DOC) to the surrounding water, resulting in more refractory dissolved organic carbon (RDOC). In “high nitrogen heatwave” conditions, photosynthetic gene expression was upregulated; bacterial abundance was also increased that can explain the reduced DOC and RDOC accumulation. The simulated heatwave reduced bacterial diversity while high nitrogen alleviated this effect. These findings suggest that the economically important alga G. lemaneiformis may lose more DOC and RDOC to nearshore waters during marine heatwave events, enhancing carbon sequestration, while nitrogen enrichment has a counteractive effect.

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Seaweed afforestation at large-scales exclusively for carbon sequestration: Critical assessment of risks, viability and the state of knowledge

Cited by 16 publications

References 137 publications

The Sea's best kept secret: the use of seaweed as a source of biohydrogen for clean and renewable energy

The Sea's best kept secret: the use of seaweed as a source of biohydrogen for clean and renewable energy

Carbon sequestration and climate change mitigation using macroalgae: a state of knowledge review

Nitrogen availability regulates the effects of a simulated marine heatwave on carbon sequestration and phycosphere bacteria of a marine crop

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