Non-monotonic emergence of order from chaos in turbulent thermo-acoustic fluid systems

Self-sustained order can emerge in complex systems due to internal feedback between coupled subsystems. Although the general mechanisms are known, the specific paths of transition to order can be different in distinct systems. Here, we present our discovery of a surprisingly non-monotonic emergence of order amidst chaos in a turbulent thermo-acoustic fluid system. Fluctuations play a vital role in determining the dynamical state and transitions in a system, as theorized by Prigogine. In this work, we use the framework of complex networks and encode the amplitude scales of fluctuations in the topology of a network. Using network entropy, we identify the amount of uncertainty in fluctuations and use it as a measure of chaotic intensity. Further, we show that network centrality measures capture the magnitude of jumps in amplitude scales due to fluctuations. We find that the competition between turbulence and nonlinear interactions leads to the non-monotonic emergence of order amidst chaos in turbulent thermo-acoustic fluid systems.