Revisiting the Seasonal Variations of Sea-Air CO2 Fluxes in the Northern East China Sea

Kim, Dong-Seon; Choi, Sang‐Hwa; Shim, Jae-Seol; Kim, Kyung‐Hee; Kim, Cheol-Ho

doi:10.3319/tao.2012.12.06.01(oc)

Cited by 14 publications

(11 citation statements)

References 20 publications

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“…The annual CO 2 uptake rate in this study area was considerably larger than the estimate for worldwide continental shelves (-1.1 mol m -2 yr -1 ; Chen and Borges 2009) and the global mean (-0.51 mol m -2 yr -1 ; Takahashi et al 2009). Kim et al (2012) reported that the annual sea-air CO 2 flux in the northern East China Sea was -2.2 ± 2.1 mol m -2 yr -1 , which is comparable to our result. Therefore, the Ulleung Basin of the East Sea, like the East China Sea, acts as a strong sink of atmospheric CO 2 .…”

Section: Factors Influencing the Seasonal Variability Of Surface Fcosupporting

confidence: 91%

“…The Tsushima Warm Current branched from the Kuroshio Current and passed through the East China Sea before entering the study area. Kim et al (2012) measured the surface fCO 2 in the northern East China Sea during four seasons; the spatial mean fCO 2 values were 311 ± 31 μatm in spring, 309 ± 53 μatm in summer, 376 ± 37 μatm in autumn, and 335 ± 17 μatm in winter. To identify the effects of lateral advection on the surface fCO 2 , the spatial mean surface fCO 2 values measured in the study area were compared with those in the East China Sea during four seasons (Table 1).…”

Section: Factors Influencing the Seasonal Variability Of Surface Fcomentioning

confidence: 99%

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Seasonal Variations of Surface fCO2 and Sea-Air CO2 Fluxes in the Ulleung Basin of the East/Japan Sea

Choi¹,

Kim²,

Shim³

et al. 2012

Terr. Atmos. Ocean. Sci.

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Temperature, salinity, chlorophyll a, and surface CO 2 fugacity (fCO 2 ) were extensively investigated in the Ulleung Basin of the East/Japan Sea during four seasonal cruises. In spring, surface fCO 2 showed large variations ranging from 260 to 356 μatm, which were considerably lower than the atmospheric CO 2 levels. Surface fCO 2 was highest (316 to 409 μatm) in summer. The central part of the study area was undersaturated with respect to atmospheric CO 2 , while the coastal and easternmost regions were oversaturated. In autumn, the entire study area was fairly undersaturated with respect to atmospheric CO 2 . In winter, surface fCO 2 ranged from 303 to 371 μatm, similar to that in autumn, despite the much lower sea surface temperature. The seasonal variation in surface fCO 2 could not be explained solely by seasonal changes in sea surface temperature and salinity. The vertical mixing, lateral transport, and sea-air CO 2 exchange considerably influenced the seasonal variation in surface fCO 2 . The Ulleung Basin of the East/Japan Sea was a sink of atmospheric CO 2 in spring, autumn, and winter, but a weak source of CO 2 to the atmosphere in summer. The annual integrated sea-air CO 2 flux in the Ulleung Basin of the East/ Japan Sea was -2.47 ± 1.26 mol m -2 yr -1 , quite similar to a previous estimate (-2.2 mol m -2 yr -1 ) in the south East/Japan Sea. This indicates that the Ulleung Basin of the East/Japan Sea acts as a strong sink of atmospheric CO 2 .

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Section: Factors Influencing the Seasonal Variability Of Surface Fcosupporting

confidence: 91%

Section: Factors Influencing the Seasonal Variability Of Surface Fcomentioning

confidence: 99%

Seasonal Variations of Surface fCO2 and Sea-Air CO2 Fluxes in the Ulleung Basin of the East/Japan Sea

Choi¹,

Kim²,

Shim³

et al. 2012

Terr. Atmos. Ocean. Sci.

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“…Prior studies have already revealed that the ECS is overall an annual net sink of atmospheric CO 2 , with significant seasonal variations (Chou et al, 2009;Chou et al, 2011;Kim et al, 2013;Peng et al, 1999;Shim et al, 2007;Tsunogai et al, 1999;Wang et al, 2000;Zhai and Dai, 2009). The ranges of present estimates are −3.3 to −6.5 in spring, −2.4 to −4.8 in summer, 0.4 to 2.9 in autumn and −13.7 to −10.4 mmol m −2 d −1 in winter.…”

Section: Introductionmentioning

confidence: 99%

“…The ranges of present estimates are −3.3 to −6.5 in spring, −2.4 to −4.8 in summer, 0.4 to 2.9 in autumn and −13.7 to −10.4 mmol m −2 d −1 in winter. However, these estimates are either based on limited (only one or a few) field surveys (Chou et al, 2009;Chou et al, 2011;Peng et al, 1999;Shim et al, 2007;Tsunogai et al, 1999;Wang et al, 2000) or suffer from spatial limitations (Kim et al, 2013;Shim et al, 2007;Tsunogai et al, 1999;Zhai and Dai, 2009). Tseng et al (2011) investigate the Changjiang diluted water induced CO 2 uptake in summer and obtain an empirical algorithm of surface water pCO 2 (partial pressure of CO 2 ) with the Changjiang discharge and sea surface temperature (SST).…”

Section: Introductionmentioning

confidence: 99%

Air–sea CO<sub>2</sub> fluxes in the East China Sea based on multiple-year underway observations

et al. 2015

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Abstract. This study reports the most comprehensive data set thus far of surface seawater pCO 2 (partial pressure of CO 2 ) and the associated air-sea CO 2 fluxes in a major ocean margin, the East China Sea (ECS), based on 24 surveys conducted in 2006 to 2011. We showed highly dynamic spatial variability in sea surface pCO 2 in the ECS except in winter, when it ranged across a narrow band of 330 to 360 µatm. We categorized the ECS into five different domains featuring with different physics and biogeochemistry to better characterize the seasonality of the pCO 2 dynamics and to better constrain the CO 2 flux. The five domains are (I) the outer Changjiang estuary and Changjiang plume, (II) the Zhejiang-Fujian coast, (III) the northern ECS shelf, (IV) the middle ECS shelf, and (V) the southern ECS shelf. In spring and summer, pCO 2 off the Changjiang estuary was as low as < 100 µatm, while it was up to > 400 µatm in autumn. pCO 2 along the Zhejiang-Fujian coast was low in spring, summer and winter (300 to 350 µatm) but was relatively high in autumn (> 350 µatm). On the northern ECS shelf, pCO 2 in summer and autumn was > 340 µatm in most areas, higher than in winter and spring. On the middle and southern ECS shelf, pCO 2 in summer ranged from 380 to 400 µatm, which was higher than in other seasons (< 350 µatm). The areaweighted CO 2 flux on the entire ECS shelf was −10.0 ± 2.0 in winter, −11.7 ± 3.6 in spring, −3.5 ± 4.6 in summer and −2.3 ± 3.1 mmol m −2 d −1 in autumn. It is important to note that the standard deviations in these flux ranges mostly reflect the spatial variation in pCO 2 rather than the bulk uncertainty. Nevertheless, on an annual basis, the average CO 2 influx into the entire ECS shelf was 6.9 ± 4.0 mmol m −2 d −1 , about twice the global average in ocean margins.

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“…The Yellow Sea Bottom Cold Water (YSBCW), which forms through winter cooling in the Yellow Sea, extends a considerable distance into the nECS (Lie 1984;Gong et al 1996). The atmospheric CO 2 sink (air to sea) during the summer in the nECS is significant (Wang et al 2000;Shim et al 2007;Kim et al 2013a). All of these processes suggest that the summer in this region is particularly dynamic due to both active physical mixing and biogeochemical processes.…”

Section: Introductionmentioning

confidence: 99%

Estimating Remineralized Phosphate and Its Remineralization Rate in the Northern East China Sea During Summer 1997: A Snapshot Study Before Three-Gorges Dam Construction

Kim¹,

Kim²,

Macdonald³

et al. 2016

Terr. Atmos. Ocean. Sci.

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The northern East China Sea (a.k.a., "The South Sea") is a dynamic zone that exerts a variety of effects on the marine ecosystem due to Three-Gorges Dam construction. As the northern East China Sea region is vulnerable to climate forcing and anthropogenic impacts, it is important to investigate how the remineralization rate in the northern East China Sea has changed in response to such external forcing. We used an historical hydrographic dataset from August 1997 to obtain a baseline for future comparison. We estimate the amount of remineralized phosphate by decomposing the physical mixing and biogeochemical process effect using water column measurements (temperature, salinity, and phosphate). The estimated remineralized phosphate column inventory ranged from 0.8 to 42.4 mmol P m -2 (mean value of 15.2 ± 12.0 mmol P m -2 ). Our results suggest that the Tsushima Warm Current was a strong contributor to primary production during the summer of 1997 in the study area. The estimated summer (June -August) remineralization rate in the region before Three-Gorges Dam construction was 18 ± 14 mmol C m -2 d -1 .

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Revisiting the Seasonal Variations of Sea-Air CO2 Fluxes in the Northern East China Sea

Cited by 14 publications

References 20 publications

Seasonal Variations of Surface fCO2 and Sea-Air CO2 Fluxes in the Ulleung Basin of the East/Japan Sea

Seasonal Variations of Surface fCO2 and Sea-Air CO2 Fluxes in the Ulleung Basin of the East/Japan Sea

Air–sea CO<sub>2</sub> fluxes in the East China Sea based on multiple-year underway observations

Estimating Remineralized Phosphate and Its Remineralization Rate in the Northern East China Sea During Summer 1997: A Snapshot Study Before Three-Gorges Dam Construction

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Revisiting the Seasonal Variations of Sea-Air CO2 Fluxes in the Northern East China Sea

Cited by 14 publications

References 20 publications

Seasonal Variations of Surface fCO2 and Sea-Air CO2 Fluxes in the Ulleung Basin of the East/Japan Sea

Seasonal Variations of Surface fCO2 and Sea-Air CO2 Fluxes in the Ulleung Basin of the East/Japan Sea

Air–sea CO&lt;sub&gt;2&lt;/sub&gt; fluxes in the East China Sea based on multiple-year underway observations

Estimating Remineralized Phosphate and Its Remineralization Rate in the Northern East China Sea During Summer 1997: A Snapshot Study Before Three-Gorges Dam Construction

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Resources

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Air–sea CO<sub>2</sub> fluxes in the East China Sea based on multiple-year underway observations