Abstract
The coupled atmosphere–ocean variability of the Indo-Pacific domain on seasonal to multidecadal time scales is investigated in CCSM4 and in observations through nonlinear Laplacian spectral analysis (NLSA). It is found that ENSO modes and combination modes of ENSO with the annual cycle exhibit a seasonally synchronized southward shift of equatorial surface zonal winds and thermocline adjustment consistent with terminating El Niño and La Niña events. The surface winds associated with these modes also generate teleconnections between the Pacific and Indian Oceans, leading to SST anomalies characteristic of the Indian Ocean dipole. The family of NLSA ENSO modes is used to study El Niño–La Niña asymmetries, and it is found that a group of secondary ENSO modes with more rapidly decorrelating temporal patterns contributes significantly to positively skewed SST and zonal wind statistics. Besides ENSO, fundamental and combination modes representing the tropospheric biennial oscillation (TBO) are found to be consistent with mechanisms for seasonally synchronized biennial variability of the Asian–Australian monsoon and Walker circulation. On longer time scales, a multidecadal pattern referred to as the west Pacific multidecadal mode (WPMM) is established to significantly modulate ENSO and TBO activity, with periods of negative SST anomalies in the western tropical Pacific favoring stronger ENSO and TBO variability. This behavior is attributed to the fact that cold WPMM phases feature anomalous decadal westerlies in the tropical central Pacific, as well as an anomalously flat zonal thermocline profile in the equatorial Pacific. Moreover, the WPMM is found to correlate significantly with decadal precipitation over Australia.
Highlights
The Indo-Pacific is the arena of prominent modes of coupled atmosphere-ocean variability spanning seasonal to multidecadal timescales
One of our main objectives has been to study the SST, surface wind, and thermocline depth patterns associated with a family of El Nino-Southern Oscillation (ENSO) modes and combination modes between ENSO and the annual cycle, which were recovered in Part I from unprocessed IndoPacific SST data
We found that in both model and observational data these patterns are in good agreement with mechanisms proposed for the phase synchronization between ENSO and the seasonal cycle (Stein et al 2011, 2014; Stuecker et al 2013, 2015a; McGregor et al 2012), whereby quadratic nonlinearities in the governing equations for the coupled atmosphere-ocean system lead to a seasonally-dependent southward shift of zonal winds following the boreal winter peak of El Nino (La Nina) events, generating an upwelling oceanic response restoring the ENSO state to neutral or La Nina (El Nino) conditions
Summary
The Indo-Pacific is the arena of prominent modes of coupled atmosphere-ocean variability spanning seasonal to multidecadal timescales. Unlike the clear dipole SST that develops in the reconstructions from the CCSM4 data during peaking El Nino/La Nina events (see, e.g, December 1175 in movie in the supplementary material), the Indian Ocean SST anomalies are of the same sign in the observational data
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