Dynamical quorum-sensing in oscillators coupled through an external medium

Many biological and physical systems exhibit population-density-dependent transitions to synchronized oscillations in a process often termed “dynamical quorum sensing”. Synchronization frequently arises through chemical communication via signaling molecules distributed through an external medium. We study a simple theoretical model for dynamical quorum sensing: a heterogenous population of limit-cycle oscillators diffusively coupled through a common medium. We show that this model exhibits a rich phase diagram with four qualitatively distinct physical mechanisms that can lead to a loss of coherent population-level oscillations, including a novel mechanism arising from effective time-delays introduced by the external medium. We derive a single pair of analytic equations that allow us to calculate phase boundaries as a function of population density and show that the model reproduces many of the qualitative features of recent experiments on Belousov–Zhabotinsky catalytic particles as well as synthetically engineered bacteria.

► A simple model of dynamical quorum sensing (DQS) is introduced. ► We find four distinct physical mechanisms that give rise to DQS transitions. ► Our model reproduces the qualitative features of recent experiments.