Imminent ocean acidification in the Arctic projected with the NCAR global coupled carbon cycle-climate model

Steinacher, Marco; Joos, F.; Frölicher, Thomas L.; Plattner, Gian‐Kasper; Doney, Scott C.

doi:10.5194/bg-6-515-2009

Cited by 454 publications

(492 citation statements)

References 58 publications

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“…Even though globally-averaged ! arag values in surface waters remain above unity for a doubling of atmospheric CO 2 , large parts of the Southern Ocean and the Arctic Ocean are projected to become undersaturated with respect to aragonite as early as 2030-2060 (Orr et al 2005;McNeil and Matear 2008;Steinacher et al, 2009). Aragonite undersaturation means that these waters will become corrosive to the aragonite and high-magnesium calcite shells secreted by a wide variety of marine organisms.…”

Section: Ocean Acidificationmentioning

confidence: 99%

A safe operating space for humanity

Rockström

Steffen

Noone

et al. 2009

Nature

9,384

5,320

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The article presents a study that investigates on the importance of identifying and quantifying planetary boundaries to prevent human activities in affecting environmental condition. The author states the industrial revolution and advancement in human civilization has caused the unstability of the environmental state that is less conducive for humans to live and affect their health condition. The author notes that planetary boundaries served a control variables to secure the safety of its citizen as well as protect the environment from shifting to dangerous levels. It also cites the different planetary boundaries, along with its impact on climate change and Earth system degradation

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Section: Ocean Acidificationmentioning

confidence: 99%

A safe operating space for humanity

Rockström

Steffen

Noone

et al. 2009

Nature

9,384

5,320

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“…Such a strategy could be used to complement (not replace) direct observations of pH, TCO 2 , and TA. Predictions of pH e and W arag e could also be used as a tool to evaluate global coupled model simulations of ocean carbon chemistry [Orr et al, 2005;Steinacher et al, 2009], identify regional vulnerabilities to ocean carbon chemistry given understanding of critical life history stages (spawning, juvenile development), and hindcast conditions for recent biological or ecological datasets for which concurrent pH, TCO 2 , and TA observations are unavailable.…”

Section: Discussionmentioning

confidence: 99%

Real-time estimation of pH and aragonite saturation state from Argo profiling floats: Prospects for an autonomous carbon observing strategy

Juranek¹,

Feely

Gilbert

et al. 2011

Geophys. Res. Lett.

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[1] We demonstrate the ability to obtain accurate estimates of pH and carbonate mineral saturation state (W) from an Argo profiling float in the NE subarctic Pacific. Using hydrographic surveys of the NE Pacific region, we develop empirical algorithms to predict pH and W using observations of temperature (T) and dissolved O 2 . We attain R 2 values greater than 0.98 and RMS errors of 0.018 (pH), 0.052 (W arag ), and 0.087 (W calc ) for data between 30-500 m, s < 27.1. After calibrating optode-based O 2 data, we apply the algorithms to T and O 2 data from an Argo profiling float to produce a 14 month time-series of estimated pH and W arag in the upper water column of the NE subarctic Pacific. Comparison to independent data collected nearby in 2010 indicates pH and W arag estimates are robust. Although the method will not allow detection of anthropogenic trends in pH or W arag , this approach will provide insight into natural variability and the key biogeochemical controls on these parameters. Most importantly, this work demonstrates that an assemblage of well-calibrated regional algorithms and Argo float data can be used as a low-cost, readily-deployable component of a global ocean carbon observing strategy.

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“…According to their model, decreased sea ice extent leads to greater atmosphere-ocean exchange of CO 2 , which in turn drives an accelerated decline for both pH and saturation states. Steinacher et al [2009], in a separate model study, demonstrated that the largest pH changes will occur in Arctic Ocean surface waters, where aragonite undersaturation is projected within a decade due to freshening by precipitation and ice melt and by increased carbon uptake as the ice cover is reduced.…”

Section: Introductionmentioning

confidence: 99%

“…Rapidly changing conditions in the Arctic, such as altered hydrological cycles, rising seawater temperature and reduction of ice cover, impact biogeochemical cycles [Arrigo et al, 2008]. Anticipated changes in saturation states in the Arctic surface waters [Steinacher et al, 2009] will propagate downstream through the CAA southward from the Labrador Shelf to the Middle Atlantic Bight. We report the current calcite and aragonite saturation states of seawater and the depths of saturation horizons based on dissolved inorganic carbon and total alkalinity measurements from the CAA and the Labrador Sea in [2003][2004][2005].…”

Section: Introductionmentioning

confidence: 99%

Calcium carbonate saturation states in the waters of the Canadian Arctic Archipelago and the Labrador Sea

Azetsu-Scott¹,

Clarke²,

Falkner³

et al. 2010

J. Geophys. Res.

117

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Ocean acidification is predicted to occur first in polar oceans. We investigated the saturation state of waters with respect to calcite (Ωcal) and aragonite (Ωarg) in six sections along an Arctic outflow pathway through the Canadian Arctic Archipelago (CAA) and into the northwestern Atlantic using dissolved inorganic carbon and total alkalinity measurements from 2003 to 2005. The study area, a key region connecting the Arctic and the North Atlantic, includes Smith Sound, Barrow Strait, Baffin Bay, Davis Strait, Hudson Strait, and the Labrador Sea. The average Ωarg in the Arctic outflow was 1.18 ± 0.17 in Barrow Strait and 1.31 ± 0.14 in Smith Sound, with areas where Ωarg < 1. The Arctic outflow through the CAA has a high content of Pacific waters, which have a low saturation state. These waters can be traced along the western Baffin Bay to Davis Strait. South of Davis Strait, this outflow is modified by mixing with slope and offshore waters of Atlantic origin and with the outflow from Hudson Strait. Despite the mixing, low saturation state water can still be identified on the southern Labrador Shelf. The aragonite saturation horizon is found at ∼150 m in Barrow Strait; at 200 m in Baffin Bay, Davis Strait, and Hudson Strait; and at 2300 m in the Labrador Sea. This study provides baseline data of the saturation states for the waters of the CAA and the northwest Atlantic. It also illustrates the downstream evolution of low saturation state Arctic outflow in the northwest Atlantic.

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Imminent ocean acidification in the Arctic projected with the NCAR global coupled carbon cycle-climate model

Cited by 454 publications

References 58 publications

A safe operating space for humanity

A safe operating space for humanity

Real-time estimation of pH and aragonite saturation state from Argo profiling floats: Prospects for an autonomous carbon observing strategy

Calcium carbonate saturation states in the waters of the Canadian Arctic Archipelago and the Labrador Sea

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