Abstract
In contrast to global warming, the subpolar North Atlantic has experienced long-term cooling throughout the 20th century. This cooling, known as the North Atlantic cold blob, has been hypothesized to arise from reduced poleward oceanic heat transport associated with a slowdown of the Atlantic meridional overturning circulation (AMOC). Here, by diagnosing historical simulations from multiple coupled climate models, we find that ocean heat transport is not the only pathway through which the AMOC modulates sea surface temperature variability. A weakened AMOC is also associated with colder, drier lower atmospheric conditions, which lead to a reduction in surface warming expected from increasing amounts of heat-trapping gases by reducing downward clear-sky longwave radiation at the surface. This radiative pathway and the oceanic processes contribute equally to the North Atlantic cold blob. These results highlight the importance of the AMOC's impact on atmospheric properties and their radiative effects.