Elevated anthropogenic CO2 invasion and stimulated carbonate dissolution in the South China Sea Basin

Abstract

Great concern has been drawn in how marginal seas respond to elevated atmospheric carbon dioxide (CO2) and changes of carbonate system during absorbing anthropogenic CO2 (Cant). Decades of Cant absorption had prominently changed the carbonate system in the South China Sea (SCS). The Cant penetrated 1200–1800 m in the SCS in 2015, deeper than it in 1997. While the inventory of Cant reached 0.66 Gt C in the entire SCS, approximately 10% higher than it in 1997.With the invasion of the Cant, the average saturated depth of aragonite and calcite became shallower. The organic carbon pump and carbonate pump in the central and southern SCS Basin were less efficient than those in the northern SCS Basin especially in the intermediate waters, which were probably caused by the different biogenic compositions and residence time from north to south. The less calcite carbonate (CaCO3) load and longer residence time in the southern SCS Basin enhanced organic matter remineralization therein and thus resulted in a less efficient organic carbon pump. The decomposition of organic matter enhanced the CaCO3 dissolution while more CaCO3 dissolution enhanced the ability of buffering the atmospheric CO2 especially in the intermediate waters. In the foreseeable future, the SCS will absorb more Cant and continue decreasing the saturation depth of CaCO3. Plain language summaryThe ocean absorbs more atmospheric carbon dioxide (CO2) and changes its carbonate system under increasing emission of anthropogenic CO2 (Cant) since the industrial evolution. Decades of Cant absorption resulted in a deeper penetration depth by several hundred meters from 1997 to 2015 in the South China Sea (SCS), and enhanced the inventory of Cant in the meantime. During the invasion of the Cant, although changes of carbonate system could not be found from the dissolved oxygen, apparent oxygen utilization (AOU), normalized dissolved inorganic carbon (NDIC) and normalized total alkalinity in the upper 1000 m between 1997 and 2015 since the discrepancies were not significant enough. But the signals of acidification in the SCS became more severe, resulting in a shallower saturated depth of aragonite and calcite.The distribution of NDIC and AOU showed distinct pattern from north to south in the SCS Basin especially in the intermediate water, indicating a less efficient organic carbon pump and carbonate pump in the central and southern SCS Basin than those in the northern SCS Basin. The composition of carbonate (CaCO3) and residence time contributed to the discrepancies of these two pumps. Under the invasion of Cant, more CaCO3 dissolved and enhanced the ability of absorbing atmospheric CO2. In the foreseeable future, the SCS will absorb more Cant and continue decreasing the saturation depth of CaCO3.