CO2 uptake in the East China Sea relying on Changjiang runoff is prone to change

Limited knowledge exists concerning the unusually large CO2 uptake capacity in the East China Sea (ECS), which is the eminent continental shelf pump for efficient transfer of atmospheric CO2 to the deep ocean. Here we show evidence of strong control of river runoff on the CO2uptake capacity of the E...

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Veröffentlicht in:	Geophysical research letters 2011-12, Vol.38 (24), p.n/a
Hauptverfasser:	Tseng, Chun-Mao, Liu, K.-K., Gong, G.-C., Shen, P.-Y., Cai, W.-J.
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Sprache:	eng
Schlagworte:	air-sea exchange Atmospheric sciences Biological oceanography Canyons Carbon dioxide Changjiang runoff Chemical oceanography Climate change CO2 uptake Continental shelves Earth Earth sciences Earth, ocean, space East China Sea Exact sciences and technology Geobiology Kuroshio River discharge River flow River plumes Rivers Runoff
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creator	Tseng, Chun-Mao Liu, K.-K. Gong, G.-C. Shen, P.-Y. Cai, W.-J.
description	Limited knowledge exists concerning the unusually large CO2 uptake capacity in the East China Sea (ECS), which is the eminent continental shelf pump for efficient transfer of atmospheric CO2 to the deep ocean. Here we show evidence of strong control of river runoff on the CO2uptake capacity of the ECS. From 8‐years of observations in the productive ECS shelf, we present the first dataset to show the complete seasonal cycle of CO2 flux, which gives an annual flux of 2.3 ± 0.4 mol C m−2 y−1 as a net sink of atmospheric CO2. Further, we found biological sequestration of CO2 taking place in the highly productive Changjiang river plume in warm seasons due to the riverine nutrient enrichment. Consequently, changes in the plume area due to changes in the Changjiang River Discharge (referred to as the Discharge hereafter) strongly affect the CO2 uptake capacity. As the Discharge may decrease due to the Three Gorges Dam operation, the Changjiang plume will probably also decrease, resulting in reduction in CO2 uptake capacity and even a shift from a CO2 sink to a source. Key Points Strong control of river runoff on the CO2 uptake capacity change in ECS The threat of the ECS shifting from a sink of atmospheric CO2 to a source Changjiang discharge decreases, resulting in the ECS CO2 uptake reduction
doi_str_mv	10.1029/2011GL049774
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Here we show evidence of strong control of river runoff on the CO2uptake capacity of the ECS. From 8‐years of observations in the productive ECS shelf, we present the first dataset to show the complete seasonal cycle of CO2 flux, which gives an annual flux of 2.3 ± 0.4 mol C m−2 y−1 as a net sink of atmospheric CO2. Further, we found biological sequestration of CO2 taking place in the highly productive Changjiang river plume in warm seasons due to the riverine nutrient enrichment. Consequently, changes in the plume area due to changes in the Changjiang River Discharge (referred to as the Discharge hereafter) strongly affect the CO2 uptake capacity. As the Discharge may decrease due to the Three Gorges Dam operation, the Changjiang plume will probably also decrease, resulting in reduction in CO2 uptake capacity and even a shift from a CO2 sink to a source. 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Res. Lett</addtitle><description>Limited knowledge exists concerning the unusually large CO2 uptake capacity in the East China Sea (ECS), which is the eminent continental shelf pump for efficient transfer of atmospheric CO2 to the deep ocean. Here we show evidence of strong control of river runoff on the CO2uptake capacity of the ECS. From 8‐years of observations in the productive ECS shelf, we present the first dataset to show the complete seasonal cycle of CO2 flux, which gives an annual flux of 2.3 ± 0.4 mol C m−2 y−1 as a net sink of atmospheric CO2. Further, we found biological sequestration of CO2 taking place in the highly productive Changjiang river plume in warm seasons due to the riverine nutrient enrichment. Consequently, changes in the plume area due to changes in the Changjiang River Discharge (referred to as the Discharge hereafter) strongly affect the CO2 uptake capacity. 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Res. Lett</addtitle><date>2011-12-28</date><risdate>2011</risdate><volume>38</volume><issue>24</issue><epage>n/a</epage><issn>0094-8276</issn><eissn>1944-8007</eissn><coden>GPRLAJ</coden><abstract>Limited knowledge exists concerning the unusually large CO2 uptake capacity in the East China Sea (ECS), which is the eminent continental shelf pump for efficient transfer of atmospheric CO2 to the deep ocean. Here we show evidence of strong control of river runoff on the CO2uptake capacity of the ECS. From 8‐years of observations in the productive ECS shelf, we present the first dataset to show the complete seasonal cycle of CO2 flux, which gives an annual flux of 2.3 ± 0.4 mol C m−2 y−1 as a net sink of atmospheric CO2. Further, we found biological sequestration of CO2 taking place in the highly productive Changjiang river plume in warm seasons due to the riverine nutrient enrichment. Consequently, changes in the plume area due to changes in the Changjiang River Discharge (referred to as the Discharge hereafter) strongly affect the CO2 uptake capacity. As the Discharge may decrease due to the Three Gorges Dam operation, the Changjiang plume will probably also decrease, resulting in reduction in CO2 uptake capacity and even a shift from a CO2 sink to a source. Key Points Strong control of river runoff on the CO2 uptake capacity change in ECS The threat of the ECS shifting from a sink of atmospheric CO2 to a source Changjiang discharge decreases, resulting in the ECS CO2 uptake reduction</abstract><cop>Washington, DC</cop><pub>Blackwell Publishing Ltd</pub><doi>10.1029/2011GL049774</doi><tpages>6</tpages></addata></record>
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subjects	air-sea exchange Atmospheric sciences Biological oceanography Canyons Carbon dioxide Changjiang runoff Chemical oceanography Climate change CO2 uptake Continental shelves Earth Earth sciences Earth, ocean, space East China Sea Exact sciences and technology Geobiology Kuroshio River discharge River flow River plumes Rivers Runoff
title	CO2 uptake in the East China Sea relying on Changjiang runoff is prone to change
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