Abstract
AbstractThe interdecadal Pacific oscillation (hereafter termed IPV, using “variability” in lieu of “oscillation”) and the Atlantic multidecadal oscillation (hereafter AMV, similar to IPV) are regulators of global mean temperature, large-scale atmospheric circulation, regional temperature and precipitation, and related extreme events. Despite a growing recognition of their importance, the combined influence of these modes of low-frequency sea surface temperature (SST) variability remains elusive given the short instrumental record and the difficulty of coupled climate models to simulate them satisfactorily. In this study, idealized simulations with two atmospheric global climate models (AGCMs) are used to show a partial cancellation of the North Pacific atmospheric response to positive IPV (i.e., deeper Aleutian low) by the concurrent positive phase of the AMV. This effect arises from a modulation of the interbasin Walker circulation that weakens deep convection in the western Pacific and the associated Rossby wave train into the northern extratropics. The weaker Aleutian low response is associated with less upward wave activity flux in the North Pacific; however, the associated stratospheric jet weakening is similar to when the +IPV alone forces the vortex, as additional upward wave activity flux over Siberia makes up the difference. While comparable warming of the polar stratosphere is found when the positive AMV is included with the positive IPV, the downward propagation of the stratospheric response is significantly reduced, which has implications for the associated surface temperature extremes. The robust anticorrelation between the positive IPV and positive AMV signals over the North Pacific and their lack of additivity highlight the need to consider the IPV–AMV interplay for anticipating decadal changes in mean climate and extreme events in the Northern Hemisphere.
Highlights
IntroductionDecadal to multidecadal internal fluctuations of sea surface temperature (SST) in the Pacific and North Atlantic drive substantial variations in Earth’s climate and are potential sources of predictability for regional temperature and/or precipitation at these time scales
A brief comparison with the results of the ARPEGE-Climat atmospheric global climate models (AGCMs) will follow in order to highlight the robustness of the atmospheric response over the North Pacific, and the model-dependent mechanisms behind this common response
This means that the modulation of the North Pacific 1IPV response by 1AMV originates from a different mechanism than the two we have identified in Whole Atmosphere Community Climate Model (WACCM): 1) suppressed upper tropospheric divergence in the tropical western Pacific and the associated 200-hPa Rossby wave train and 2) reduced downward propagation of the stratospheric response
Summary
Decadal to multidecadal internal fluctuations of sea surface temperature (SST) in the Pacific and North Atlantic drive substantial variations in Earth’s climate and are potential sources of predictability for regional temperature and/or precipitation at these time scales The leading mode of interannual to multidecadal SST variability in the Pacific is termed the Pacific decadal oscillation (PDO), the first empirical orthogonal function (EOF) of monthly SST anomalies in the Pacific poleward of 208N (Mantua et al 1997). For information regarding reuse of this content and general copyright information, consult the AMS Copyright Policy (www.ametsoc.org/PUBSReuseLicenses)
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