Synchronization, Collective Oscillations, and Information Flow in Duplex Networks

TL;DR

This paper studies duplex networks with reactive interlayer links, revealing how frequency differences lead to collective oscillations and complex rhythmic activity through microscopic information transfer mechanisms.

Contribution

It introduces a model of duplex networks with reactive links showing how partial synchronization and collective oscillations emerge from frequency differences.

Findings

Networks self-organize into multimodal oscillations

Frequency differences induce complex rhythmic activity

Information transfer underpins mode interactions

Abstract

In many real-world systems, partial synchronization is the dominant dynamical regime and, in systems such as the brain, is often accompanied by collective oscillations in which multiple overlapping modes interact to produce complex rhythmic activity. Here, we investigate duplex networks with reactive interlayer links, where full synchronization cannot be achieved. We show that when interlayer frequency differences between mirror nodes are uniformly distributed with sufficient width, the network self-organizes into collective macroscopic oscillations composed of multiple interacting modes. By linking macroscopic phase transitions to microscopic directed information transfer between nodes, we uncover the mechanisms underlying the emergence of these multimodal dynamics.