Impact of recent climate variability on oceanic CO2 uptake in a global ocean biogeochemistry model
While atmospheric CO2 concentrations have been increasing during recent decades due to anthropogenic emissions, the ocean has acted as a sink for atmospheric carbon. Essentially, the global air-sea flux of CO2 showed a trend towards more oceanic uptake as expected from increasing emissions. Yet, the...
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| Format: | Thesis |
| Language: | English |
| Published: |
2021
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| Online Access: | https://oceanrep.geomar.de/id/eprint/56755/ https://oceanrep.geomar.de/id/eprint/56755/1/Bunsen_Master_2021.pdf https://doi.org/10.3289/MSC_2021_Bunsen |
| Summary: | While atmospheric CO2 concentrations have been increasing during recent decades due to anthropogenic emissions, the ocean has acted as a sink for atmospheric carbon. Essentially, the global air-sea flux of CO2 showed a trend towards more oceanic uptake as expected from increasing emissions. Yet, the oceanic CO2 uptake also responded to climate change and fluctuated due to climate variability and variations in the growth rate of atmospheric CO2. So far, the drivers of the variability in oceanic CO2 uptake are not conclusively understood. In this thesis, the global ocean biogeochemistry model FESOM-1.4-REcoM is used to quantify the effects of climate change and of the increasing atmospheric CO2 concentration on the trend in the oceanic carbon uptake during the period 1958-2019 (62 years). Two approaches are applied: (1) Offline diagnostics based on a linear approximation relating the trends in the sea surface temperature, dissolved inorganic carbon, alkalinity, salinity plus freshwater fluxes, wind velocity and sea-ice concentration to the trend in the CO2 flux and (2) a model experiment with the historical forcing fields compared to simulations in which certain forcing fields (e.g. winds and the atmospheric forcing fields that control the sea surface temperature) are replaced by a repeated year forcing in order to isolate their effects on the CO2 flux. In FESOM-1.4-REcoM, the ocean took up 1:85 PgCyr-1 of atmospheric CO2 on average during the simulated period. The ocean carbon sink increased with a trend of 23:8 TgCyr-1 per yr. In a simulation with rising atmospheric CO2 concentrations but without climate change and variability, the trend in oceanic carbon uptake was 27% higher than that, suggesting that climate variability has substantially reduced the uptake over the simulated period. Of this, a trend towards more outgassing of 2:9 TgCyr-1 per yr was driven by the change and variability in winds, which was particularly relevant in the polar and subpolar regions. Hereby, a comparison between the offline and ... |
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