The evolution of deep ocean chemistry and respired carbon in the Eastern equatorial Pacific over the last deglaciation
The evolution of deep ocean chemistry and respired carbon in the Eastern equatorial Pacific over the last deglaciation
It has been shown that the deep Eastern Equatorial Pacific (EEP) region was poorly ventilated during the Last Glacial Maximum (LGM) relative to Holocene values. This finding suggests a more efficient biological pump, which indirectly supports the idea of increased carbon storage in the deep ocean contributing to lower atmospheric CO2 during the last glacial. However, proxies related to respired carbon are needed in order to directly test this proposition. Here we present Cibicides wuellerstorfi B/Ca ratios from Ocean Drilling Program Site 1240 measured by laser ablation inductively coupled plasma mass spectrometry (LA-ICPMS) as a proxy for deep water carbonate saturation state (Δ[CO32−], and therefore [CO32−]), along with δ13C measurements. In addition, the U/Ca ratio in foraminiferal coatings has been analyzed as an indicator of oxygenation changes. Our results show lower [CO32−], δ13C, and [O2] values during the LGM, which would be consistent with higher respired carbon levels in the deep EEP driven, at least in part, by reduced deep water ventilation. However, the difference between LGM and Holocene [CO32−] observed at our site is relatively small, in accordance with other records from across the Pacific, suggesting that a “counteracting” mechanism, such as seafloor carbonate dissolution, also played a role. If so, this mechanism would have increased average ocean alkalinity, allowing even more atmospheric CO2 to be “sequestered” by the ocean. Therefore, the deep Pacific Ocean very likely stored a significant amount of atmospheric CO2 during the LGM, specifically due to a more efficient biological carbon pump and also an increase in average ocean alkalinity.
1371-1385
Fuente, Maria de la
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Calvo, Eva
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Skinner, Luke
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Pelejero, Carles
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Evans, David
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Müller, Wolfgang
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Povea, Patricia
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Cacho, Isabel
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20 December 2017
Fuente, Maria de la
aa94b7e3-cc30-45d9-85df-fddccc85b2d6
Calvo, Eva
481687a9-d3d5-4868-9fe8-08f4955bcc88
Skinner, Luke
3b31eb32-9abb-43ff-a821-6bccc6cdbe2a
Pelejero, Carles
519663e3-9509-432d-bd7d-c749497cfdb3
Evans, David
878c65c7-eab9-4362-896b-166e165eb94b
Müller, Wolfgang
360a71f7-0b47-4ff3-8c32-1912d70401aa
Povea, Patricia
0ad9e621-7c7b-4b9f-a072-1402d6c14550
Cacho, Isabel
d716f5dc-c21e-4adc-851e-9c9ebb2ee0d7
Fuente, Maria de la, Calvo, Eva, Skinner, Luke, Pelejero, Carles, Evans, David, Müller, Wolfgang, Povea, Patricia and Cacho, Isabel
(2017)
The evolution of deep ocean chemistry and respired carbon in the Eastern equatorial Pacific over the last deglaciation.
Paleoceanography, 32 (12), .
(doi:10.1002/2017PA003155).
Abstract
It has been shown that the deep Eastern Equatorial Pacific (EEP) region was poorly ventilated during the Last Glacial Maximum (LGM) relative to Holocene values. This finding suggests a more efficient biological pump, which indirectly supports the idea of increased carbon storage in the deep ocean contributing to lower atmospheric CO2 during the last glacial. However, proxies related to respired carbon are needed in order to directly test this proposition. Here we present Cibicides wuellerstorfi B/Ca ratios from Ocean Drilling Program Site 1240 measured by laser ablation inductively coupled plasma mass spectrometry (LA-ICPMS) as a proxy for deep water carbonate saturation state (Δ[CO32−], and therefore [CO32−]), along with δ13C measurements. In addition, the U/Ca ratio in foraminiferal coatings has been analyzed as an indicator of oxygenation changes. Our results show lower [CO32−], δ13C, and [O2] values during the LGM, which would be consistent with higher respired carbon levels in the deep EEP driven, at least in part, by reduced deep water ventilation. However, the difference between LGM and Holocene [CO32−] observed at our site is relatively small, in accordance with other records from across the Pacific, suggesting that a “counteracting” mechanism, such as seafloor carbonate dissolution, also played a role. If so, this mechanism would have increased average ocean alkalinity, allowing even more atmospheric CO2 to be “sequestered” by the ocean. Therefore, the deep Pacific Ocean very likely stored a significant amount of atmospheric CO2 during the LGM, specifically due to a more efficient biological carbon pump and also an increase in average ocean alkalinity.
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Published date: 20 December 2017
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Local EPrints ID: 502466
URI: http://eprints.soton.ac.uk/id/eprint/502466
ISSN: 0883-8305
PURE UUID: 5dcf0ed8-76b5-445b-8b4c-0b93e21b7fd9
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Date deposited: 26 Jun 2025 17:07
Last modified: 27 Jun 2025 02:09
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Author:
Maria de la Fuente
Author:
Eva Calvo
Author:
Luke Skinner
Author:
Carles Pelejero
Author:
David Evans
Author:
Wolfgang Müller
Author:
Patricia Povea
Author:
Isabel Cacho
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