Litcius/Paper detail

Tipping point and noise-induced transients in ecological networks

Meng Yu, Ying-Cheng Lai, Celso Grebogi

2020Journal of The Royal Society Interface58 citationsDOIOpen Access PDF

Abstract

A challenging and outstanding problem in interdisciplinary research is to understand the interplay between transients and stochasticity in high-dimensional dynamical systems. Focusing on the tipping-point dynamics in complex mutualistic networks in ecology constructed from empirical data, we investigate the phenomena of noise-induced collapse and noise-induced recovery. Two types of noise are studied: environmental (Gaussian white) noise and state-dependent demographic noise. The dynamical mechanism responsible for both phenomena is a transition from one stable steady state to another driven by stochastic forcing, mediated by an unstable steady state. Exploiting a generic and effective two-dimensional reduced model for real-world mutualistic networks, we find that the average transient lifetime scales algebraically with the noise amplitude, for both environmental and demographic noise. We develop a physical understanding of the scaling laws through an analysis of the mean first passage time from one steady state to another. The phenomena of noise-induced collapse and recovery and the associated scaling laws have implications for managing high-dimensional ecological systems.

Topics & Concepts

Noise (video)Statistical physicsTipping point (physics)White noiseScalingSteady state (chemistry)Forcing (mathematics)EcologyEnvironmental noiseScaling lawDynamical systems theoryTheoretical ecologyComputer sciencePhysicsEnvironmental scienceMathematicsBiologyEngineeringTelecommunicationsArtificial intelligencePopulationAtmospheric sciencesPhysical chemistryQuantum mechanicsElectrical engineeringGeometrySociologyDemographySound (geography)AcousticsChemistryImage (mathematics)Ecosystem dynamics and resilienceEarth Systems and Cosmic EvolutionSustainability and Ecological Systems Analysis