Litcius/Paper detail

The weakening AMOC under extreme climate change

Gaurav Madan, Ada Gjermundsen, Silje Christine Iversen, J. H. LaCasce

2023Climate Dynamics33 citationsDOIOpen Access PDF

Abstract

Abstract Changes in the Atlantic Meridional Overturning Circulation (AMOC) in the quadrupled CO 2 experiments conducted under the sixth Coupled Model Intercomparison Project (CMIP6) are examined. Increased CO 2 triggers extensive Arctic warming, causing widespread melting of sea ice. The resulting freshwater spreads southward, first from the Labrador Sea and then the Nordic Seas, and proceeds along the eastern coast of North America. The freshwater enters the subpolar gyre north of the separated Gulf Stream, the North Atlantic Current. This decreases the density gradient across the current and the current weakens in response, reducing the inflow to the deepwater production regions. The AMOC cell weakens in tandem, first near the North Atlantic Current and then spreading to higher and lower latitudes. This contrasts with the common perception that freshwater caps the convection regions, stifling deepwater production; rather, it is the inflow to the subpolar gyre that is suppressed. Changes in surface temperature have a much weaker effect, and there are no consistent changes in local or remote wind forcing among the models. Thus an increase in freshwater discharge, primarily from the Labrador Sea, is the precursor to AMOC weakening in these simulations.

Topics & Concepts

Ocean gyreClimatologyOceanographyCurrent (fluid)UpwellingShutdown of thermohaline circulationCoupled model intercomparison projectClimate changeGeologyEnvironmental scienceClimate modelForcing (mathematics)North Atlantic Deep WaterThermohaline circulationSubtropicsFisheryBiologyClimate variability and modelsOceanographic and Atmospheric ProcessesArctic and Antarctic ice dynamics