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Higher order interactions in complex networks of phase oscillators promote abrupt synchronization switching

Per Sebastian Skardal, Alex Arenas

2020Communications Physics291 citationsDOIOpen Access PDF

Abstract

Abstract Synchronization processes play critical roles in the functionality of a wide range of both natural and man-made systems. Recent work in physics and neuroscience highlights the importance of higher-order interactions between dynamical units, i.e., three- and four-way interactions in addition to pairwise interactions, and their role in shaping collective behavior. Here we show that higher-order interactions between coupled phase oscillators, encoded microscopically in a simplicial complex, give rise to added nonlinearity in the macroscopic system dynamics that induces abrupt synchronization transitions via hysteresis and bistability of synchronized and incoherent states. Moreover, these higher-order interactions can stabilize strongly synchronized states even when the pairwise coupling is repulsive. These findings reveal a self-organized phenomenon that may be responsible for the rapid switching to synchronization in many biological and other systems that exhibit synchronization without the need of particular correlation mechanisms between the oscillators and the topological structure.

Topics & Concepts

Synchronization (alternating current)BistabilityComplex networkPairwise comparisonSynchronization networksPhysicsCoupling (piping)Topology (electrical circuits)Complex systemStatistical physicsHysteresisPhase (matter)Complex dynamicsNonlinear systemPhase transitionPhase synchronizationWork (physics)Computer scienceOrder (exchange)Nonlinear dynamical systemsMultistabilityBiological systemDynamical systems theoryCollective behaviorDynamics (music)Range (aeronautics)Living systemsNetwork dynamicsControl theory (sociology)Self-organizationProperty (philosophy)Nonlinear Dynamics and Pattern Formationstochastic dynamics and bifurcationNeural dynamics and brain function
Higher order interactions in complex networks of phase oscillators promote abrupt synchronization switching | Litcius