Global Warming Pattern Formation: The Role of Ocean Heat Uptake
Shineng Hu, Shang‐Ping Xie, Sarah M. Kang
Abstract
Abstract This study investigates the formation mechanism of the ocean surface warming pattern in response to a doubling CO 2 with a focus on the role of ocean heat uptake (or ocean surface heat flux change, Δ Q net ). We demonstrate that the transient patterns of surface warming and rainfall change simulated by the dynamic ocean–atmosphere coupled model (DOM) can be reproduced by the equilibrium solutions of the slab ocean–atmosphere coupled model (SOM) simulations when forced with the DOM Δ Q net distribution. The SOM is then used as a diagnostic inverse modeling tool to decompose the CO 2 -induced thermodynamic warming effect and the Δ Q net (ocean heat uptake)–induced cooling effect. As Δ Q net is largely positive (i.e., downward into the ocean) in the subpolar oceans and weakly negative at the equator, its cooling effect is strongly polar amplified and opposes the CO 2 warming, reducing the net warming response especially over Antarctica. For the same reason, the Δ Q net -induced cooling effect contributes significantly to the equatorially enhanced warming in all three ocean basins, while the CO 2 warming effect plays a role in the equatorial warming of the eastern Pacific. The spatially varying component of Δ Q net , although globally averaged to zero, can effectively rectify and lead to decreased global mean surface temperature of a comparable magnitude as the global mean Δ Q net effect under transient climate change. Our study highlights the importance of air–sea interaction in the surface warming pattern formation and the key role of ocean heat uptake pattern.