Fluid-network relations: decay laws meet with spatial self-similarity, scale-invariance, and control scaling

TL;DR

This paper uncovers how fluid properties like energy decay and enstrophy relate to network features such as self-similarity and scale-invariance, revealing power-law behaviors and control dynamics that deepen understanding of fluid structures.

Contribution

It introduces a novel framework linking fluid mechanics with network topology, demonstrating power-law relations and control scaling in fluid-network interactions.

Findings

Deviations from self-similarity follow power-law scaling with fluid properties.

Scale-invariance breaking extents also scale with fluid properties in power-law manners.

Control propagation speed decays over time, governed by fluid properties.

Abstract

Diverse implicit structures of fluids are discovered lately, providing opportunities to study the physics of fluids applying network analysis. Although considerable works devote to identifying informative network structures of fluids, we have limited understanding about the information these networks convey about fluids. To analyze how fluid mechanics is embodied in network topology or vice versa, we reveal a set of fluid-network relations that quantify the interactions between fundamental fluid properties (e.g., kinetic energy and enstrophy decay laws) and defining network characteristics (e.g., spatial self-similarity, scale-invariance, and control scaling). By analyzing spatial self-similarity in classic and generalized contexts, we first assess the self-similarity of vortical interactions in fluid flows. Deviations from self-similarity in networks exhibit power-law scaling behaviors with respect to fluid properties, suggesting the diversity among vortex as essential to self-similar fluid flows. Then, the same paradigm is adopted to investigate scale-invariance using renormalization groups, which reveals that the breaking extents of scale-invariance in networks, similar to those of spatial self-similarity, also scale with fluid properties in power-law manners. Furthermore, we define a control problem on networks to study the propagation of perturbations through vortical interactions over different ranges. The minimum cost of controlling vortical networks exponentially scales with range diameters (i.e., control distances), whose growth rates experiences temporal decays. We show that this temporal decay speed is fully determined by fluid properties in power-law scaling behaviours. In summary, these fluid-network relations enable a deeper understanding of implicit fluid structures and their interactions with fluid dynamics.