Literature DB >> 20651119

Decrease in the CO2 uptake capacity in an ice-free Arctic Ocean basin.

Wei-Jun Cai1, Liqi Chen, Baoshan Chen, Zhongyong Gao, Sang H Lee, Jianfang Chen, Denis Pierrot, Kevin Sullivan, Yongchen Wang, Xinping Hu, Wei-Jen Huang, Yuanhui Zhang, Suqing Xu, Akihiko Murata, Jacqueline M Grebmeier, E Peter Jones, Haisheng Zhang.   

Abstract

It has been predicted that the Arctic Ocean will sequester much greater amounts of carbon dioxide (CO2) from the atmosphere as a result of sea ice melt and increasing primary productivity. However, this prediction was made on the basis of observations from either highly productive ocean margins or ice-covered basins before the recent major ice retreat. We report here a high-resolution survey of sea-surface CO2 concentration across the Canada Basin, showing a great increase relative to earlier observations. Rapid CO2 invasion from the atmosphere and low biological CO2 drawdown are the main causes for the higher CO2, which also acts as a barrier to further CO2 invasion. Contrary to the current view, we predict that the Arctic Ocean basin will not become a large atmospheric CO2 sink under ice-free conditions.

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Year:  2010        PMID: 20651119     DOI: 10.1126/science.1189338

Source DB:  PubMed          Journal:  Science        ISSN: 0036-8075            Impact factor:   47.728


  8 in total

1.  Water Mass Controlled Vertical Stratification of Bacterial and Archaeal Communities in the Western Arctic Ocean During Summer Sea-Ice Melting.

Authors:  Puthiya Veettil Vipindas; Siddarthan Venkatachalam; Thajudeen Jabir; Eun Jin Yang; Kyoung-Ho Cho; Jinyoung Jung; Youngju Lee; Kottekkatu Padinchati Krishnan
Journal:  Microb Ecol       Date:  2022-03-28       Impact factor: 4.552

2.  Do invasive quagga mussels alter CO2 dynamics in the Laurentian Great Lakes?

Authors:  Peng Lin; Laodong Guo
Journal:  Sci Rep       Date:  2016-12-20       Impact factor: 4.379

Review 3.  A synthesis of the arctic terrestrial and marine carbon cycles under pressure from a dwindling cryosphere.

Authors:  Frans-Jan W Parmentier; Torben R Christensen; Søren Rysgaard; Jørgen Bendtsen; Ronnie N Glud; Brent Else; Jacobus van Huissteden; Torsten Sachs; Jorien E Vonk; Mikael K Sejr
Journal:  Ambio       Date:  2017-02       Impact factor: 5.129

4.  Changes in the Arctic Ocean Carbon Cycle With Diminishing Ice Cover.

Authors:  Michael DeGrandpre; Wiley Evans; Mary-Louise Timmermans; Richard Krishfield; Bill Williams; Michael Steele
Journal:  Geophys Res Lett       Date:  2020-06-13       Impact factor: 4.720

5.  Baseline monitoring of the western Arctic Ocean estimates 20% of Canadian basin surface waters are undersaturated with respect to aragonite.

Authors:  Lisa L Robbins; Jonathan G Wynn; John T Lisle; Kimberly K Yates; Paul O Knorr; Robert H Byrne; Xuewu Liu; Mark C Patsavas; Kumiko Azetsu-Scott; Taro Takahashi
Journal:  PLoS One       Date:  2013-09-11       Impact factor: 3.240

6.  Pacific Walrus and climate change: observations and predictions.

Authors:  James G Maccracken
Journal:  Ecol Evol       Date:  2012-07-22       Impact factor: 2.912

7.  Bacterial communities of surface mixed layer in the Pacific sector of the western Arctic Ocean during sea-ice melting.

Authors:  Dukki Han; Ilnam Kang; Ho Kyung Ha; Hyun Cheol Kim; Ok-Sun Kim; Bang Yong Lee; Jang-Cheon Cho; Hor-Gil Hur; Yoo Kyung Lee
Journal:  PLoS One       Date:  2014-01-31       Impact factor: 3.240

8.  Disparate acidification and calcium carbonate desaturation of deep and shallow waters of the Arctic Ocean.

Authors:  Yiming Luo; Bernard P Boudreau; Alfonso Mucci
Journal:  Nat Commun       Date:  2016-09-23       Impact factor: 14.919
  8 in total

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