Ocean acidification from 1997 to 2011 in the subarctic western North Pacific Ocean

Wakita, Masashi; Watanabe, Shuichi; Honda, Makio C.; Nagano, Akira; Kimoto, Katsunori; Matsumoto, Kazuhiko; Kitamura, Minoru; Sasaki, Ken‐ichi; Kawakami, Hiroyoshi; Fujiki, Tetsuichi; Sasaoka, Kosei; Nakano, Yoshiyuki; Murata, Akihiko

doi:10.5194/bg-10-7817-2013

Cited by 41 publications

(38 citation statements)

References 42 publications

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“…The results of the decomposition of ΔΩ arg were similar to those for ΔΩ cal (Figure 6, blue 47°N, 160°E), Wakita et al [2013] reported rates of À0.0055 a À1 to À0.0077 a À1 and À0.0035 a À1 to À0.0048 a À1 for Ω cal and Ω arg , respectively. Using repeat hydrography data, Murata and Saito [2012] found a maximum rate of Ω arg decrease of 0.034 a À1 at 200-300 dbar at 20°N along the 179°E meridian.…”

Section: 1002/2014gb004908supporting

confidence: 69%

Detecting the progression of ocean acidification from the saturation state of CaCO₃ in the subtropical South Pacific

Murata

Hayashi

Kumamoto

et al. 2015

Global Biogeochemical Cycles

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Progression of ocean acidification in the subtropical South Pacific was investigated by using high-quality data from trans-Pacific zonal section at 17°S (World Ocean Circulation Experiment section P21) collected in 1994 and 2009. During this 15 year period, the CaCO 3 saturation state of seawater with respect to calcite (Ω cal ) and aragonite (Ω arg ) in the upper water column (<400 dbar) decreased at rates of 0.037 a À1 and 0.025 a À1, respectively, east of 145°W longitude; these rates are among the fastest in the world's oceans. In contrast, at longitudes 170°E-145°W, Ω cal and Ω arg decreased relatively slowly, at 0.008 a À1 and 0.005 a À1, respectively. The Ω arg saturation horizon occurred at a depth of about 1200 dbar at the westernmost end of the section and shoaled eastward to about 20 dbar. From 1994 to 2009, it migrated upward at a rate of 5.2 dbar a À1 west of 145°W. Decomposition of the temporal changes of Ω (ΔΩ) showed that the accumulation of anthropogenic CO 2 in the ocean accounted for more than half of ΔΩ. The more rapid rate of decline of Ω in the eastern section was attributable to a relatively large contribution of organic matter remineralization, whereas the slower rate in the central section was attributed to a decrease of anthropogenic CO 2 uptake caused by rising water temperatures. An important finding of this study was that acidification of the upper water column was enhanced by processes related to the oxygen minimum zone in the eastern subtropical South Pacific Ocean.

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Section: 1002/2014gb004908supporting

confidence: 69%

Detecting the progression of ocean acidification from the saturation state of CaCO₃ in the subtropical South Pacific

Murata

Hayashi

Kumamoto

et al. 2015

Global Biogeochemical Cycles

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“…A detailed and long-term observation in the subtropical North Pacific off the southern coast of Japan showed that Ωar of surface water is ~3.5 during the summer, but decreases to lower than 3.0 during the winter (at 33°40′N-34°00′N; Ishii et al (2011)). In the western subarctic gyre further north, a similar seasonal pattern in surface Ωar was observed, but with a larger variation and lower values for both summer (~2.5) and winter (~1.3) (at ~45°N; Wakita et al 2013). From these observations, the Ωar of waters in Tokyo Bay would be ~3 with a maximum value in summer, if there is no alternation of water properties by processes within the bay.…”

Section: Study Areasupporting

confidence: 56%

“…Ishii et al 2011;Wakita et al 2013). The very high primary production and resulting remineralization of organic matter in this shallow and eutrophicated bay are the major causes of such large variations.…”

Section: Discussionmentioning

confidence: 99%

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Calcium carbonate saturation and ocean acidification in Tokyo Bay, Japan

et al. 2015

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“…Calculated pH trends for the North Atlantic Gyre suggest a decrease of −0.0022 ± 0.0004 units yr −1 over the period 1981-2007(Lauvset and Gruber, 2014. In the North Pacific, a pH decrease of −0.0011 ± 0.0004 units yr −1 from 1997 to 2011 has been calculated ( Table 3; Wakita et al, 2013).…”

Section: Updates To Ar5mentioning

confidence: 92%

An updated synthesis of the observed and projected impacts of climate change on the chemical, physical and biological processes in the oceans

et al. 2015

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The 5th Assessment Report (AR5) of the Intergovernmental Panel on Climate Change (IPCC) states with very high certainty that anthropogenic emissions have caused measurable changes in the physical ocean environment. These changes are summarized with special focus on those that are predicted to have the strongest, most direct effects on ocean biological processes; namely, ocean warming and associated phenomena (including stratification and sea level rise) as well as deoxygenation and ocean acidification. The biological effects of these changes are then discussed for microbes (including phytoplankton), plants, animals, warm and cold-water corals, and ecosystems. The IPCC AR5 highlighted several areas related to both the physical and biological processes that required further research. As a rapidly developing field, there have been many pertinent studies published since the cut off dates for the AR5, which have increased our understanding of the processes at work. This study undertook an extensive review of recently published literature to update the findings of the AR5 and provide a synthesized review on the main issues facing future oceans. The level of detail provided in the AR5 and subsequent work provided a basis for constructing projections of the state of ocean ecosystems in 2100 under two the Representative Concentration Pathways RCP4.5 and 8.5. Finally the review highlights notable additions, clarifications and points of departure from AR5 provided by subsequent studies.

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Ocean acidification from 1997 to 2011 in the subarctic western North Pacific Ocean

Cited by 41 publications

References 42 publications

Detecting the progression of ocean acidification from the saturation state of CaCO₃ in the subtropical South Pacific

Detecting the progression of ocean acidification from the saturation state of CaCO₃ in the subtropical South Pacific

Calcium carbonate saturation and ocean acidification in Tokyo Bay, Japan

An updated synthesis of the observed and projected impacts of climate change on the chemical, physical and biological processes in the oceans

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Ocean acidification from 1997 to 2011 in the subarctic western North Pacific Ocean

Cited by 41 publications

References 42 publications

Detecting the progression of ocean acidification from the saturation state of CaCO3 in the subtropical South Pacific

Detecting the progression of ocean acidification from the saturation state of CaCO3 in the subtropical South Pacific

Calcium carbonate saturation and ocean acidification in Tokyo Bay, Japan

An updated synthesis of the observed and projected impacts of climate change on the chemical, physical and biological processes in the oceans

Contact Info

Product

Resources

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Detecting the progression of ocean acidification from the saturation state of CaCO₃ in the subtropical South Pacific

Detecting the progression of ocean acidification from the saturation state of CaCO₃ in the subtropical South Pacific