$Understanding the origin of extreme events in El Ni\~{n}o-Southern Oscillation$

Understanding the origin of extreme events in El Ni\~{n}o-Southern Oscillation

We investigate a low-dimensional slow-fast model to understand the dynamical origin of El Niño-Southern Oscillation. A close inspection of the system dynamics using several bifurcation plots reveals that a sudden large expansion of the attractor occurs at a critical system parameter via a type of in...

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Veröffentlicht in:	arXiv.org 2020-06
Hauptverfasser:	Arnob Ray, Rakshit, Sarbendu, Basak, Gopal K, Dana, Syamal K, Ghosh, Dibakar
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Sprache:	eng
Schlagworte:	Amplitudes Autoregressive models Bifurcations Critical point El Nino Inspection Physics - Adaptation and Self-Organizing Systems Physics - Chaotic Dynamics Southern Oscillation System dynamics
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creator	Arnob Ray Rakshit, Sarbendu Basak, Gopal K Dana, Syamal K Ghosh, Dibakar
description	We investigate a low-dimensional slow-fast model to understand the dynamical origin of El Niño-Southern Oscillation. A close inspection of the system dynamics using several bifurcation plots reveals that a sudden large expansion of the attractor occurs at a critical system parameter via a type of interior crisis. This interior crisis evolves through merging of a cascade of period-doubling and period-adding bifurcations that leads to the origin of occasional amplitude-modulated extremely large events. More categorically, a situation similar to homoclinic chaos arises near the critical point, however, atypical global instability evolves as a channel-like structure in phase space of the system that modulates variability of amplitude and return time of the occasional large events and makes a difference from the homoclinic chaos. The slow-fast timescale of the low-dimensional model plays an important role on the onset of occasional extremely large events. Such extreme events are characterized by their heights when they exceed a threshold level measured by a mean-excess function. The probability density of events' height displays multimodal distribution with an upper-bounded tail. We identify the dependence structure of interevent intervals to understand the predictability of return time of such extreme events using autoregressive integrated moving average model and box plot analysis.
doi_str_mv	10.48550/arxiv.2006.11969
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subjects	Amplitudes Autoregressive models Bifurcations Critical point El Nino Inspection Physics - Adaptation and Self-Organizing Systems Physics - Chaotic Dynamics Southern Oscillation System dynamics
title	Understanding the origin of extreme events in El Ni\~{n}o-Southern Oscillation
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