From collective oscillation to chimera state in a nonlocally coupled excitable system

Abstract

Chimera states, which consist of coexisting domains of spatially coherent and incoherent dynamics, have been widely found in nonlocally coupled oscillatory systems. We demonstrate that chimera states can emerge from excitable systems under nonlocal coupling in which isolated units only allow for the equilibrium. We theoretically reveal that nonlocal coupling-induced collective oscillation is behind the occurrence of the chimera states. We find two different types of chimera states, phase-chimera states and excitability-chimera states, depending on the coupling strength. At weak coupling strength where collective oscillation is localized around the unstable homogeneous equilibrium, the chimera states are similar to the ones in nonlocally coupled phase oscillators. For the chimera states at strong coupling strength, the dynamics of both coherent units and incoherent units shift back and forth between low-amplitude oscillation induced by collective oscillation and high-amplitude oscillation induced by excitability of local units.