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Multidecadal changes in biology influence the variability of the North Atlantic carbon sink
The North Atlantic Ocean is the most intense marine sink for anthropogenic carbon dioxide (CO _2 ) in the world’s oceans, showing high variability and substantial changes over recent decades. However, the contribution of biology to the variability and trend of this sink is poorly understood. Here we use in situ plankton measurements, alongside observation-based sea surface CO _2 data from 1982 to 2020, to investigate the biological influence on the CO _2 sink. Our results demonstrate that long term variability in the CO _2 sink in the North Atlantic is associated with changes in phytoplankton abundance and community structure. These data show that within the subpolar regions of the North Atlantic, phytoplankton biomass is increasing, while a decrease is observed in the subtropics, which supports model predictions of climate-driven changes in productivity. These biomass trends are synchronous with increasing temperature, changes in mixing and an increasing uptake of atmospheric CO _2 in the subpolar North Atlantic. Our results highlight that phytoplankton play a significant role in the variability as well as the trends of the CO _2 uptake from the atmosphere over recent decades.
Multidecadal changes in biology influence the variability of the North Atlantic carbon sink
The North Atlantic Ocean is the most intense marine sink for anthropogenic carbon dioxide (CO _2 ) in the world’s oceans, showing high variability and substantial changes over recent decades. However, the contribution of biology to the variability and trend of this sink is poorly understood. Here we use in situ plankton measurements, alongside observation-based sea surface CO _2 data from 1982 to 2020, to investigate the biological influence on the CO _2 sink. Our results demonstrate that long term variability in the CO _2 sink in the North Atlantic is associated with changes in phytoplankton abundance and community structure. These data show that within the subpolar regions of the North Atlantic, phytoplankton biomass is increasing, while a decrease is observed in the subtropics, which supports model predictions of climate-driven changes in productivity. These biomass trends are synchronous with increasing temperature, changes in mixing and an increasing uptake of atmospheric CO _2 in the subpolar North Atlantic. Our results highlight that phytoplankton play a significant role in the variability as well as the trends of the CO _2 uptake from the atmosphere over recent decades.
Multidecadal changes in biology influence the variability of the North Atlantic carbon sink
Clare Ostle (author) / Peter Landschützer (author) / Martin Edwards (author) / Martin Johnson (author) / Sunke Schmidtko (author) / Ute Schuster (author) / Andrew J Watson (author) / Carol Robinson (author)
2022
Article (Journal)
Electronic Resource
Unknown
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