Global Trends in Air‐Water CO 2 Exchange Over Seagrass Meadows Revealed by Atmospheric Eddy Covariance

Coastal vegetated habitats like seagrass meadows can mitigate anthropogenic carbon emissions by sequestering CO 2 as “blue carbon” (BC). Already, some coastal ecosystems are actively managed to enhance BC storage, with associated BC stocks included in national greenhouse gas inventories. However, the extent to which BC burial fluxes are enhanced or counteracted by other carbon fluxes, especially air‐water CO 2 flux (FCO 2 ) remains poorly understood. In this study, we synthesized all available direct FCO 2 measurements over seagrass meadows made using atmospheric Eddy Covariance, across a globally representative range of ecotypes. Of the four sites with seasonal data coverage, two were net CO 2 sources, with average FCO 2 equivalent to 44%–115% of the global average BC burial rate. At the remaining sites, net CO 2 uptake was 101%–888% of average BC burial. A wavelet coherence analysis demonstrated that FCO 2 was most strongly related to physical factors like temperature, wind, and tides. In particular, tidal forcing was a key driver of global‐scale patterns in FCO 2 , likely due to a combination of lateral carbon exchange, bottom‐driven turbulence, and pore‐water pumping. Lastly, sea‐surface drag coefficients were always greater than the prediction for the open ocean, supporting a universal enhancement of gas‐transfer in shallow coastal waters. Our study points to the need for a more comprehensive approach to BC assessments, considering not only organic carbon storage, but also air‐water CO 2 exchange, and its complex biogeochemical and physical drivers.