Abstract
Abstract. Macroalgal beds have drawn attention as one of the vegetated coastal ecosystems that act as atmospheric CO2 sinks. Although macroalgal metabolism as well as inorganic and organic carbon flows are important pathways for CO2 uptake by macroalgal beds, the relationships between macroalgal metabolism and associated carbon flows are still poorly understood. In the present study, we investigated carbon flows, including air–water CO2 exchange and budgets of dissolved inorganic carbon, total alkalinity, and dissolved organic carbon (DOC), in a temperate macroalgal bed during the productive months of the year. To assess the key mechanisms responsible for atmospheric CO2 uptake by the macroalgal bed, we estimated macroalgal metabolism and lateral carbon flows (i.e., carbon exchanges between the macroalgal bed and the offshore area) by using field measurements of carbon species, a field-bag method, a degradation experiment, and mass-balance modeling in a temperate Sargassum bed over a diurnal cycle. Our results showed that macroalgal metabolism and lateral carbon flows driven by water exchange affected air–water CO2 exchange in the macroalgal bed and the surrounding waters. Macroalgal metabolism caused overlying waters to contain low concentrations of CO2 and high concentrations of DOC that were efficiently exported offshore from the macroalgal bed. These results indicate that the exported water can potentially lower CO2 concentrations in the offshore surface water and enhance atmospheric CO2 uptake. Furthermore, the Sargassum bed exported 6 %–35 % of the macroalgal net community production (NCP; 302–1378 mmol C m−2 d−1) as DOC to the offshore area. The results of degradation experiments showed that 56 %–78 % of macroalgal DOC was refractory DOC (RDOC) that persisted for 150 d; thus, the Sargassum bed exported 5 %–20 % of the macroalgal NCP as RDOC. Our findings suggest that macroalgal beds in habitats associated with high water exchange rates can create significant CO2 sinks around them and export a substantial amount of DOC to offshore areas.
Highlights
Vegetated coastal ecosystems provide a variety of ecosystem functions that support diverse biological communities and biogeochemical processes
The dissolved organic carbon (DOC) concentrations were higher in the macroalgal bed than at the offshore site, but the difference between them was significant only in March (p = 0.010; Fig. 3 and Table S2). f CO2 was strongly correlated with dissolved inorganic carbon (DIC) in both February and March (Fig. 4)
Our results show that the Sargassum bed exported 5 %–20 % of the macroalgal net community production (NCP) as refractory DOC (RDOC) that persisted for 150 d (Fig. 7)
Summary
Vegetated coastal ecosystems provide a variety of ecosystem functions that support diverse biological communities and biogeochemical processes. Recent recognition of the carbon sequestration function of these ecosystems has led to the development of blue carbon strategies for mitigating the adverse effects of global climate change via conservation and restoration of these ecosystems (Nellemann et al, 2009; Duarte et al, 2013; Macreadie et al, 2019). Carbon flows that sequester atmospheric CO2 in marine ecosystems over timescales of at least several decades are crucial for the mitigation of climate change (McLeod et al, 2011; Macreadie et al, 2019). K. Watanabe et al.: Macroalgal metabolism and lateral carbon flows of vegetated coastal ecosystems has far been focused on salt marshes, seagrasses, and mangroves, which develop their own organic-rich sediments (Macreadie et al, 2019). Macroalgal beds have the potential to regulate carbon dynamics in coastal ecosystems
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