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First-order synchronization transition in a large population of strongly coupled relaxation oscillators

Dumitru Călugăru, Jan Frederik Totz, Erik A. Martens, Harald Engel

2020Science Advances37 citationsDOIOpen Access PDF

Abstract

Onset and loss of synchronization in coupled oscillators are of fundamental importance in understanding emergent behavior in natural and man-made systems, which range from neural networks to power grids. We report on experiments with hundreds of strongly coupled photochemical relaxation oscillators that exhibit a discontinuous synchronization transition with hysteresis, as opposed to the paradigmatic continuous transition expected from the widely used weak coupling theory. The resulting first-order transition is robust with respect to changes in network connectivity and natural frequency distribution. This allows us to identify the relaxation character of the oscillators as the essential parameter that determines the nature of the synchronization transition. We further support this hypothesis by revealing the mechanism of the transition, which cannot be accounted for by standard phase reduction techniques.

Topics & Concepts

Synchronization (alternating current)Relaxation oscillatorPopulationOrder (exchange)Relaxation (psychology)Transition (genetics)Statistical physicsPhysicsComputer scienceTopology (electrical circuits)MathematicsBiologyNeuroscienceQuantum mechanicsDemographyCombinatoricsGeneticsVoltageEconomicsVoltage-controlled oscillatorFinanceSociologyGeneNonlinear Dynamics and Pattern FormationNeural dynamics and brain functionstochastic dynamics and bifurcation
First-order synchronization transition in a large population of strongly coupled relaxation oscillators | Litcius