Long-term surface pCO2 trends from observations and models
We estimate regional long-term surface ocean pCO 2 growth rates using all available underway and bottled biogeochemistry data collected over the past four decades. These observed regional trends are compared with those simulated by five state-of-the-art Earth system models over the historical period...
| Main Authors: | , , , , , , , , |
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| Format: | Article in Journal/Newspaper |
| Language: | unknown |
| Published: |
2014
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| Subjects: | |
| Online Access: | https://figshare.com/articles/journal_contribution/Long-term_surface_pCO2_trends_from_observations_and_models/22955915 |
| _version_ | 1826781379449323520 |
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| author | Tjiputra, JF Olsen, A Bopp, L Lenton, A Pfeil, B Roy, T Segschneider, J Totterdell, I Heinze, C |
| author_facet | Tjiputra, JF Olsen, A Bopp, L Lenton, A Pfeil, B Roy, T Segschneider, J Totterdell, I Heinze, C |
| author_sort | Tjiputra, JF |
| collection | Research from University Of Tasmania |
| description | We estimate regional long-term surface ocean pCO 2 growth rates using all available underway and bottled biogeochemistry data collected over the past four decades. These observed regional trends are compared with those simulated by five state-of-the-art Earth system models over the historical period. Oceanic pCO 2 growth rates faster than the atmospheric growth rates indicate decreasing atmospheric CO 2 uptake, while ocean pCO 2 growth rates slower than the atmospheric growth rates indicate increasing atmospheric CO 2 uptake. Aside from the western subpolar North Pacific and the subtropical North Atlantic, our analysis indicates that the current observation-based basin-scale trends may be underestimated, indicating that more observations are needed to determine the trends in these regions. Encouragingly, good agreement between the simulated and observed pCO 2 trends is found when the simulated fields are subsampled with the observational coverage. In agreement with observations, we see that the simulated pCO 2 trends are primarily associated with the increase in surface dissolved inorganic carbon (DIC) associated with atmospheric carbon uptake, and in part by warming of the sea surface. Under the RCP8.5 future scenario, DIC continues to be the dominant driver of pCO 2 trends, with little change in the relative contribution of SST. However, the changes in the hydrological cycle play an increasingly important role. For the contemporary (1970–2011) period, the simulated regional pCO 2 trends are lower than the atmospheric growth rate over 90% of the ocean. However, by year 2100 more than 40% of the surface ocean area has a higher oceanic pCO 2 trend than the atmosphere, implying a reduction in the atmospheric CO 2 uptake rate. The fastest pCO 2 growth rates are projected for the subpolar North Atlantic, while the high-latitude Southern Ocean and eastern equatorial Pacific have the weakest growth rates, remaining below the atmospheric pCO 2 growth rate. Our work also highlights the importance and need for a ... |
| format | Article in Journal/Newspaper |
| genre | North Atlantic Southern Ocean |
| genre_facet | North Atlantic Southern Ocean |
| geographic | Pacific Southern Ocean |
| geographic_facet | Pacific Southern Ocean |
| id | ftunivtasmanfig:oai:figshare.com:article/22955915 |
| institution | Open Polar |
| language | unknown |
| op_collection_id | ftunivtasmanfig |
| op_relation | 102.100.100/565415 |
| op_rights | In Copyright |
| publishDate | 2014 |
| record_format | openpolar |
| spelling | ftunivtasmanfig:oai:figshare.com:article/22955915 2025-03-16T15:31:05+00:00 Long-term surface pCO2 trends from observations and models Tjiputra, JF Olsen, A Bopp, L Lenton, A Pfeil, B Roy, T Segschneider, J Totterdell, I Heinze, C 2014-01-01T00:00:00Z https://figshare.com/articles/journal_contribution/Long-term_surface_pCO2_trends_from_observations_and_models/22955915 unknown 102.100.100/565415 In Copyright Chemical oceanography surface pCO2 ocean CO2 sinks Earth system models CMIP5 projections ocean biogeochemistry Text Journal contribution 2014 ftunivtasmanfig 2025-02-17T09:48:24Z We estimate regional long-term surface ocean pCO 2 growth rates using all available underway and bottled biogeochemistry data collected over the past four decades. These observed regional trends are compared with those simulated by five state-of-the-art Earth system models over the historical period. Oceanic pCO 2 growth rates faster than the atmospheric growth rates indicate decreasing atmospheric CO 2 uptake, while ocean pCO 2 growth rates slower than the atmospheric growth rates indicate increasing atmospheric CO 2 uptake. Aside from the western subpolar North Pacific and the subtropical North Atlantic, our analysis indicates that the current observation-based basin-scale trends may be underestimated, indicating that more observations are needed to determine the trends in these regions. Encouragingly, good agreement between the simulated and observed pCO 2 trends is found when the simulated fields are subsampled with the observational coverage. In agreement with observations, we see that the simulated pCO 2 trends are primarily associated with the increase in surface dissolved inorganic carbon (DIC) associated with atmospheric carbon uptake, and in part by warming of the sea surface. Under the RCP8.5 future scenario, DIC continues to be the dominant driver of pCO 2 trends, with little change in the relative contribution of SST. However, the changes in the hydrological cycle play an increasingly important role. For the contemporary (1970–2011) period, the simulated regional pCO 2 trends are lower than the atmospheric growth rate over 90% of the ocean. However, by year 2100 more than 40% of the surface ocean area has a higher oceanic pCO 2 trend than the atmosphere, implying a reduction in the atmospheric CO 2 uptake rate. The fastest pCO 2 growth rates are projected for the subpolar North Atlantic, while the high-latitude Southern Ocean and eastern equatorial Pacific have the weakest growth rates, remaining below the atmospheric pCO 2 growth rate. Our work also highlights the importance and need for a ... Article in Journal/Newspaper North Atlantic Southern Ocean Research from University Of Tasmania Pacific Southern Ocean |
| spellingShingle | Chemical oceanography surface pCO2 ocean CO2 sinks Earth system models CMIP5 projections ocean biogeochemistry Tjiputra, JF Olsen, A Bopp, L Lenton, A Pfeil, B Roy, T Segschneider, J Totterdell, I Heinze, C Long-term surface pCO2 trends from observations and models |
| title | Long-term surface pCO2 trends from observations and models |
| title_full | Long-term surface pCO2 trends from observations and models |
| title_fullStr | Long-term surface pCO2 trends from observations and models |
| title_full_unstemmed | Long-term surface pCO2 trends from observations and models |
| title_short | Long-term surface pCO2 trends from observations and models |
| title_sort | long-term surface pco2 trends from observations and models |
| topic | Chemical oceanography surface pCO2 ocean CO2 sinks Earth system models CMIP5 projections ocean biogeochemistry |
| topic_facet | Chemical oceanography surface pCO2 ocean CO2 sinks Earth system models CMIP5 projections ocean biogeochemistry |
| url | https://figshare.com/articles/journal_contribution/Long-term_surface_pCO2_trends_from_observations_and_models/22955915 |