Disentangling North Atlantic ocean-atmosphere coupling using circulation analogues

The coupled nature of the ocean-atmosphere system frequently makes understanding the direction of causality difficult in ocean-atmosphere interactions. This study presents a method to decompose turbulent heat fluxes into a component which is directly forced by atmospheric circulation, and a residual which is assumed to be primarily `ocean-forced'. This method is applied to the North Atlantic in a 500-year pre-industrial control run using the Met Office's HadGEM3-GC3.1-MM model. The method identifies residual heat flux modes largely associated with variations in ocean circulation and shows that these force equivalent barotropic circulation anomalies in the atmosphere. The first of these modes is characterised by the ocean warming the atmosphere along the Gulf Stream and North Atlantic Current and the second by a dipole of cooling in the western subtropical North Atantic and warming in the sub-polar North Atlantic. Analysis of atmosphere-only simulations confirms that these heat flux patterns are indeed forcing the atmospheric circulation changes seen in the pre-industrial control run. It is found that the Gulf Stream plays a critical role in the atmospheric circulation response to decadal ocean variability in this model. More generally, the heat flux dynamical decomposition method provides a useful way to establish causality in ocean-atmosphere interactions which could easily be applied to other ocean basins and to either models or reanalysis datasets.