Abstract
Abstract. Limited observations exist for a reliable assessment of annual CO2 uptake that takes into consideration the strong seasonal variation in the river-dominated East China Sea (ECS). Here we explore seasonally representative CO2 uptakes by the whole East China Sea derived from observations over a 14-year period. We firstly identified the biological sequestration of CO2 taking place in the highly productive, nutrient-enriched Changjiang River plume, dictated by the Changjiang River discharge in warm seasons. We have therefore established an empirical algorithm as a function of sea surface temperature (SST) and Changjiang River discharge (CRD) for predicting sea surface pCO2. Syntheses based on both observations and models show that the annually averaged CO2 uptake from atmosphere during the period 1998–2011 was constrained to about 1.8 ± 0.5 mol C m−2 yr−1. This assessment of annual CO2 uptake is more reliable and representative, compared to previous estimates, in terms of temporal and spatial coverage. Additionally, the CO2 time series, exhibiting distinct seasonal pattern, gives mean fluxes of −3.7 ± 0.5, −1.1 ± 1.3, −0.3 ± 0.8 and −2.5 ± 0.7 mol C m−2 yr−1 in spring, summer, fall and winter, respectively, and also reveals apparent interannual variations. The flux seasonality shows a strong sink in spring and a weak source in late summer–mid-fall. The weak sink status during warm periods in summer–fall is fairly sensitive to changes of pCO2 and may easily shift from a sink to a source altered by environmental changes under climate change and anthropogenic forcing.
Highlights
Continental shelves generally receive large loads of carbon from land, on the one hand, and sustain rapid biological growth and biogeochemical cycling with rates much higher than those in the open ocean, on the other hand (Walsh, 1991)
In order to evaluate whether the cruise data are representative of the entire East China Sea (ECS), we compared the areal mean values of Advanced Very-High Resolution Radiometer (AVHRR)-sea surface temperature (SST) from the two model areas against the observed average SST data
The areal mean SST data obtained on our cruise investigations can represent the variability of the areal mean value of the entire ECS
Summary
Continental shelves generally receive large loads of carbon from land, on the one hand, and sustain rapid biological growth and biogeochemical cycling with rates much higher than those in the open ocean, on the other hand (Walsh, 1991) Despite their relatively small total surface area (∼ 8 % of the whole ocean area), they overall play a significant role in the global biogeochemical cycle as a net sink of atmospheric CO2 (0.2–0.5 Gt C yr−1), which represents 10–30 % of the current estimate of global oceanic CO2 uptake (Borges et al, 2005; Cai et al, 2006; Chen and Borges, 2009; Laruelle et al, 2010). Tseng et al.: Air–sea CO2 exchange fluxes in the East China Sea carbon uptake of 0.01–0.03 Gt C, representing 0.5–2.0 % of the global uptake This implies a relatively high CO2 uptake rate compared to other ocean regions. The resultant algorithm aimed to improve the quantification of shelf CO2 uptake capacity in the ECS eventually leads to a time series of the air–sea CO2 exchange flux from 1998 to 2011 that yields an annual mean value of unsurpassed accuracy after an examination of different gas-transfer algorithms
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