An assessment of CO2 uptake in the Arctic Ocean from 1985 to 2018

As a contribution to the Regional Carbon Cycle Assessment and Processes phase 2 (RECCAP2) project, we present synthesized estimates of Arctic Ocean sea-air CO2 fluxes and their uncertainties from 8 surface ocean pCO2-observation products, 18 ocean biogeochemical hindcast and data assimilation models...

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Main Authors: Yasunaka, Sayaka, Manizza, Manfredi, Terhaar, Jens, Olsen, Are, Yamaguchi, Ryohei, Landschützer, Peter, Watanabe, Eiji, Carroll, Dustin, Adiwara, Hanani, Müller, Jens Daniel, Hauck, Judith
Format: Other/Unknown Material
Language:unknown
Published: Authorea, Inc. 2023
Subjects:
Arctic
Arctic Ocean
Climate change
Sea ice
Online Access:http://dx.doi.org/10.22541/essoar.168476524.42265823/v1
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spelling crwinnower:10.22541/essoar.168476524.42265823/v1 2024-06-02T08:01:12+00:00 An assessment of CO2 uptake in the Arctic Ocean from 1985 to 2018 Yasunaka, Sayaka Manizza, Manfredi Terhaar, Jens Olsen, Are Yamaguchi, Ryohei Landschützer, Peter Watanabe, Eiji Carroll, Dustin Adiwara, Hanani Müller, Jens Daniel Hauck, Judith 2023 http://dx.doi.org/10.22541/essoar.168476524.42265823/v1 unknown Authorea, Inc. posted-content 2023 crwinnower https://doi.org/10.22541/essoar.168476524.42265823/v1 2024-05-07T14:19:21Z As a contribution to the Regional Carbon Cycle Assessment and Processes phase 2 (RECCAP2) project, we present synthesized estimates of Arctic Ocean sea-air CO2 fluxes and their uncertainties from 8 surface ocean pCO2-observation products, 18 ocean biogeochemical hindcast and data assimilation models and 6 atmospheric inversions. For the period of 1985−2018, the Arctic Ocean was a net sink of CO2 of 116 ± 4 TgC yr−1 in the pCO2 products and 92 ± 30 TgC yr−1 in the models. The CO2 uptake peaks in late summer and early autumn, and is low in winter when sea ice inhibits sea-air fluxes. The long-term mean CO2 uptake in the Arctic Ocean is primarily caused by steady-state fluxes of natural carbon (70 ± 15 %), and enhanced by the atmospheric CO2 increase (19 ± 5 %) and climate change (11 ± 18 %). The annual mean CO2 uptake increased from 1985 to 2018 at a rate of 31 ±13 TgC yr−1dec-1 in the pCO2 products and 10 ± 4 TgC yr−1dec-1 in the models. Moreover, 77 ± 38 % of the trend in the net CO2 uptake over time is caused by climate change, primarily due to rapid sea ice loss in recent years. Both, the mean CO2 uptake and the trend, is substantially weaker in the atmospheric inversions. Uncertainties across all estimates are large, in the pCO2 products because of scarcity of observations and in the models because of missing processes. Other/Unknown Material Arctic Arctic Ocean Climate change Sea ice The Winnower Arctic Arctic Ocean
institution Open Polar
collection The Winnower
op_collection_id crwinnower
language unknown
description As a contribution to the Regional Carbon Cycle Assessment and Processes phase 2 (RECCAP2) project, we present synthesized estimates of Arctic Ocean sea-air CO2 fluxes and their uncertainties from 8 surface ocean pCO2-observation products, 18 ocean biogeochemical hindcast and data assimilation models and 6 atmospheric inversions. For the period of 1985−2018, the Arctic Ocean was a net sink of CO2 of 116 ± 4 TgC yr−1 in the pCO2 products and 92 ± 30 TgC yr−1 in the models. The CO2 uptake peaks in late summer and early autumn, and is low in winter when sea ice inhibits sea-air fluxes. The long-term mean CO2 uptake in the Arctic Ocean is primarily caused by steady-state fluxes of natural carbon (70 ± 15 %), and enhanced by the atmospheric CO2 increase (19 ± 5 %) and climate change (11 ± 18 %). The annual mean CO2 uptake increased from 1985 to 2018 at a rate of 31 ±13 TgC yr−1dec-1 in the pCO2 products and 10 ± 4 TgC yr−1dec-1 in the models. Moreover, 77 ± 38 % of the trend in the net CO2 uptake over time is caused by climate change, primarily due to rapid sea ice loss in recent years. Both, the mean CO2 uptake and the trend, is substantially weaker in the atmospheric inversions. Uncertainties across all estimates are large, in the pCO2 products because of scarcity of observations and in the models because of missing processes.
format Other/Unknown Material
author Yasunaka, Sayaka
Manizza, Manfredi
Terhaar, Jens
Olsen, Are
Yamaguchi, Ryohei
Landschützer, Peter
Watanabe, Eiji
Carroll, Dustin
Adiwara, Hanani
Müller, Jens Daniel
Hauck, Judith
spellingShingle Yasunaka, Sayaka
Manizza, Manfredi
Terhaar, Jens
Olsen, Are
Yamaguchi, Ryohei
Landschützer, Peter
Watanabe, Eiji
Carroll, Dustin
Adiwara, Hanani
Müller, Jens Daniel
Hauck, Judith
An assessment of CO2 uptake in the Arctic Ocean from 1985 to 2018
author_facet Yasunaka, Sayaka
Manizza, Manfredi
Terhaar, Jens
Olsen, Are
Yamaguchi, Ryohei
Landschützer, Peter
Watanabe, Eiji
Carroll, Dustin
Adiwara, Hanani
Müller, Jens Daniel
Hauck, Judith
author_sort Yasunaka, Sayaka
title An assessment of CO2 uptake in the Arctic Ocean from 1985 to 2018
title_short An assessment of CO2 uptake in the Arctic Ocean from 1985 to 2018
title_full An assessment of CO2 uptake in the Arctic Ocean from 1985 to 2018
title_fullStr An assessment of CO2 uptake in the Arctic Ocean from 1985 to 2018
title_full_unstemmed An assessment of CO2 uptake in the Arctic Ocean from 1985 to 2018
title_sort assessment of co2 uptake in the arctic ocean from 1985 to 2018
publisher Authorea, Inc.
publishDate 2023
url http://dx.doi.org/10.22541/essoar.168476524.42265823/v1
geographic Arctic
Arctic Ocean
geographic_facet Arctic
Arctic Ocean
genre Arctic
Arctic Ocean
Climate change
Sea ice
genre_facet Arctic
Arctic Ocean
Climate change
Sea ice
op_doi https://doi.org/10.22541/essoar.168476524.42265823/v1
_version_ 1800745506365767680

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