Response of Atmospheric pCO2 to Glacial Changes in the Southern Ocean Amplified by Carbonate Compensation

Atmospheric carbon dioxide concentration (pCO(2)) varies by about 100 ppm during glacial-interglacial cycles. Previous studies suggest that the strongly stratified Southern Ocean at the Last Glacial Maximum increases the oceanic storage of carbon, but the glacial reduction of atmospheric pCO(2) simulated by ocean general circulation models (OGCMs) does not reach 100 ppm. One candidate for the underestimation is that carbonate compensation is not explicitly incorporated in the previous OGCM simulations. Therefore, we quantitatively evaluate the impact of carbonate compensation on the glacial atmospheric pCO(2) by using an OGCM coupled with an ocean sediment model. As suggested by previous box model studies, our OGCM simulations show that the enhanced Southern Ocean stratification amplifies the decrease in atmospheric pCO(2) due to carbonate compensation. Considering the enhanced stratification in the Southern Ocean, we obtain a 26-ppm drawdown of atmospheric pCO(2) by carbonate compensation, and the full reduction from our pre-industrial simulation reaches 73 ppm. Both the increase in ventilation ages in the deep Atlantic and Southern Oceans and the growth of export production in the subantarctic region reduce the bottom-water carbonate ion and promote deposited carbonate dissolution. Consequently, a greater imbalance between the river inflow and burial loss of carbonate rises ocean alkalinity, lowering atmospheric pCO(2). We suggest that the reproducibility of the Southern Ocean process is essential for controlling the magnitude of atmospheric pCO(2) decline due to carbonate compensation.