Abstract
The subpolar North Atlantic represents a key region for global climate, but most numerical models still have well-described limitations in correctly simulating the local circulation patterns. Here, we present the analysis of a 30-year run with a global eddy-resolving (1/12°) version of the NEMO ocean model. Compared to the 1° and 1/4° equivalent versions, this simulation more realistically represents the shape of the Subpolar Gyre, the position of the North Atlantic Current, and the Gulf Stream separation. Other key improvements are found in the representation of boundary currents, multi-year variability of temperature and depth of winter mixing in the Labrador Sea, and the transport of overflows at the Greenland–Scotland Ridge. However, the salinity, stratification and mean depth of winter mixing in the Labrador Sea, and the density and depth of overflow water south of the sill, still present challenges to the model. This simulation also provides further insight into the spatio-temporal development of the warming event observed in the Subpolar Gyre in the mid 1990s, which appears to coincide with a phase of increased eddy activity in the southernmost part of the gyre. This may have provided a gateway through which heat would have propagated into the gyre's interior.
Highlights
The subpolar North Atlantic is one of the climatically relevant regions of the global ocean (Rhein et al, 2011)
The first step of the validation of ORCA12 in the subpolar North Atlantic consists of a comparison of surface variables from the numerical model output with observations, and an analysis of the overall structure of the circulation, to assess whether the main currents are resolved by the model and follow realistic pathways
Local key features will be further investigated in specific regions of interest, such as the overflows from the Nordic Seas in the Denmark Strait and in the Faroe Bank Channel, and the mixed layer depth (MLD) and the Deep Western Boundary Current (DWBC) in the Labrador Sea
Summary
The subpolar North Atlantic is one of the climatically relevant regions of the global ocean (Rhein et al, 2011). The subpolar North Atlantic is a crucial region for the modulation of the temperate climate of north-western Europe, and the dynamics of the Subpolar Gyre (SPG) determine the rate of deep-water formation (Katsman et al, 2004). These newly formed, or significantly modified, water masses constitute the cold lower limb of the AMOC, and variations induced by climate change are most likely to arise in this area. Waters of tropical and subtropical origin form the warm and salty upper branch of the AMOC; through the Gulf Stream, North Atlantic Current (NAC), and Irminger Current, the AMOC transports these warm and salty waters to the subpolar North Atlantic
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