Critical Behavior at the Onset of Multichimera States in a Coupled-Oscillator Array

Abstract

We numerically investigate the onset of multi-chimera states in a linear array of coupled oscillators. As the phase delay α is increased, they exhibit a continuous transition from the globally synchronized state to the multichimera state consisting of asynchronous and synchronous domains. Large-scale simulations show that the fraction of asynchronous sites a obeys the power law a (α - αc)βa, and that the spatio-temporal gaps between asynchronous sites show power-law distributions at the critical point. The critical exponents are distinct from those of the (1+1)-dimensional directed percolation and other absorbing-state phase transitions, indicating that this transition belongs to a new class of non-equilibrium critical phenomena. Crucial roles are played by traveling waves that rejuvenate asynchronous clusters by mediating non-local interactions between them.