Investigating a nonlinear characteristic of El Nino events by conditional nonlinear optimal perturbation

We use the approach of conditional nonlinear optimal perturbation (CNOP) to investigate the optimal precursory disturbances in a theoretical El Nino-Southern Oscillation (ENSO) model and then an intermediate model. By exploring the dynamical behaviors of the El Nino events caused by these CNOP-type precursors, a characteristic for this kind of theoretical El Nino events is shown, i.e., the stronger El Nino events tend to decay faster and have shorter durations of the decaying phase. By examining the observed El Nino events, it is found that the Nino-3.4 SSTA are more potential than the Nino-3 SSTA in illustrating the decaying characteristic of the theoretical El Nino events. In particular, it is the Nino-3.4 indices for the strong El Nino events during 1981-2007 that roughly show the decaying characteristic. Based on the physics of the theoretical model, the mechanism responsible for the above decaying characteristic of strong El Nino events is explored. The analysis demonstrates that the property of the stronger El Nino event decaying faster can be realized only through the linear dynamics with the combined effects of the rising of thermocline and the mean upwelling, but that of the stronger El Nino event having a shorter duration of the decaying phase results from a nonlinear mechanism. It is shown that the nonlinearity related to the anomalous temperature advection in the tropical Pacific shortens the duration of the decaying phase for El Nino event. The stronger the El Nino event, the stronger the nonlinearity, then the more considerable the suppressing of the nonlinearity on the duration of the decaying phase for El Nino event. This explains why the stronger El Nino events have shorter durations of the decaying phase. Also, this sheds light on why the observed strong El Nino events are more likely to show this characteristic. (C) 2008 Elsevier B.V. All rights reserved.