Srinivas G., Vialard Jérôme, Lengaigne Matthieu, Izumo Takeshi, Guilyardi E. (2022). Relative contributions of sea surface temperature and atmospheric nonlinearities to ENSO asymmetrical rainfall response. Journal of Climate, 35 (12), p. 3725-3745. ISSN 0894-8755.
Titre du document
Relative contributions of sea surface temperature and atmospheric nonlinearities to ENSO asymmetrical rainfall response
Srinivas G., Vialard Jérôme, Lengaigne Matthieu, Izumo Takeshi, Guilyardi E.
Source
Journal of Climate, 2022,
35 (12), p. 3725-3745 ISSN 0894-8755
Here, we investigate the relative roles of atmospheric nonlinearities and asymmetrical sea surface temperature (SST) forcing in the El Nino-Southern Oscillation (ENSO) asymmetrical rainfall response. Applying a vertically integrated water vapor budget to the ERA5 reanalysis leads to a simple analytical equation for precipitation anomalies. This formulation reveals that ENSO rainfall anomalies are dominated by the linear component of the dynamical term (i.e., the anomalous moisture convergence due to the effect of circulation anomalies on climatological humidity). Nonlinearities in this term and the linear thermodynamical term (i.e., the effect of climatological circulation on humidity anomalies) both strengthen central Pacific rainfall anomalies for both ENSO phases. In contrast, the nonlinear term associated with the effect of anomalous divergence on anomalous moisture (i.e., the mixed term) weakens La Nina dry and strengthens El Nino wet anomalies, in particular during extreme El Nino events when it contributes to about 40% of the eastern Pacific wet anomalies. Overall, atmospheric nonlinearities directly account for similar to 70% of the positively skewed ENSO rainfall distribution east of the date line, and similar to 50% of the negatively skewed rainfall distribution in the western Pacific. The remaining ENSO rainfall asymmetries are attributable to the asymmetrical ENSO SST pattern. This asymmetrical SST pattern also has contributions from atmospheric nonlinearities through the Bjerknes feedback loop, in addition to those from oceanic nonlinearities. Our estimates are thus likely a lower bound of the contribution of atmospheric nonlinearities to the overall ENSO rainfall asymmetry.
Plan de classement
Sciences fondamentales / Techniques d'analyse et de recherche [020]
;
Sciences du milieu [021]
;
Limnologie physique / Océanographie physique [032]
