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Role of the Gulf Stream and Kuroshio-Oyashio Systems in Large-Scale Atmosphere-Ocean Interaction: A Review. Young-oh Kwon et al. Outline. Intorduction Processes affecting the SST variability in the WBCs WBCs and the basin-scale climate variability
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Role of the Gulf Stream and Kuroshio-Oyashio Systems in Large-Scale Atmosphere-Ocean Interaction: A Review Young-oh Kwon et al.
Outline • Intorduction • Processes affecting the SST variability in the WBCs • WBCs and the basin-scale climate variability • Performance of climate models on simulation of WBC variability • Outstanding issue
Introduction • There are “exceptionally” strong atmosphere-ocean interaction over West Boundary Current region. • Mean and Variances(SSTA) • Interannual and longer time scale • Heat transport • Atmosphere response to WBC STTAs with several issues
Interesting issues • The Connection between frontal-scale boundary layer ocean-atmosphere interaction and the basin-scale variability. • Potential changes in WBC ocean duce to global warming. • The relationship between the Meridional overturning circulation and Gulf Stream in North Atlantic. • Interbasin connection between the KOE and GS variability.
Processes affecting the SST variability in the WBCs • Shift of oceanic fronts • Oceanic advection • Surface heat fluxes • Ekman transport • Reemergence mechanism • Remote wind stress curl forcing communicated via oceanic Rossby wave • Tropical atmosphere teleconnections
Shift of oceanic front • Decadal SST variability is particularly strong along the SubArctic Frontal Zones.
Oceanic advection • In the WBCs on interannual and longer time scales is determined mainly by anomalous geostrophic advection, which tends to dominate over Ekman advection and Qnet.
Surface heat flux • Qnet in the WBC
Ekman Transport • Ekman transport responds quickly to changes in surface wind and can generate SSTA. • To reinforce the Qnet in mid-latitudes because stronger westerlies cool the ocean by the sensible and latent heat fluxes and by southward Ekman transport. • The cross-frontal cold Ekman advection lowers the near-surface stratification on the warmer side of the front and enhance vertical mixing.
Remote wind stress curl forcing communicated via oceanic Rossby wave
WBCs and the basin-scale climate variability • Decadal SST variability in the WBCs • Oceanic dynamics and decadal variability • Surface heat flux damping and implications • Decadal variability in atmosphere-ocean coupled general circulation models
Oceanic dynamics and decadal variability • As the Rossby waves propagate westward, they integrate the stochastic forcing to increase the variance and dominant period of dynamic ocean properties until reaching a maximum near the WBC. • The spatial resonance mechanisms could generate a decadal peak in the ocean by stochastic atmosphere.
Decadal variability in atmosphere-ocean coupled general circulation models • Coupled climate models generally indicate that ocean-atmosphere interaction in WBC regions is a key factor in generating extropical decadal variability. • Although earlier studies suggested that North Atlantic decadal variability in SST was primarily reflecting a passive response to the atmospheric forcing.
Performance of climate models on simulation of WBC variability • High-resolution ocean simulations • Simulation of the Kuroshio and Gulf Stream at non-eddy-permitting resolution • Atmospheric simulations
High-resolution ocean simulations • For KOE: • KE’s path variability can be tied largely to wind forcing. • For GS: • Interaction between DWBC.
Simulation of the Kuroshio and Gulf Stream at non-eddy-permitting resolution
Outstanding issues • How are the frontal-scale and basin-scale atmosphere-ocean interactions related? • What is the large scale atmospheric circulation/wind stress curl response to the WBC SSTA • Global warming and the WBCs • Relation between the Gulf Stream and the MOC • Connection between GS and KOE variability