Interaction between hairy surfaces and turbulence for different surface time scales

TL;DR

This study numerically investigates how hairy, filamentous surfaces interact with turbulence near walls, revealing that their resonance frequency significantly influences flow modification and drag, depending on filament elasticity and mass.

Contribution

It demonstrates that the resonance frequency of hairy surfaces determines their interaction with turbulence, showing different flow modifications based on filament properties.

Findings

Low resonance frequency filaments conform to elongated streaks.

High resonance frequency filaments increase permeability and drag.

Filament elasticity and mass control flow behavior near surfaces.

Abstract

Surfaces with filamentous structures are ubiquitous in nature on many different scales, ranging from forests to micrometer-sized cilia in organs. Hairy surfaces are elastic and porous, and it is not fully understood how they modify turbulence near a wall. The interaction between hairy surfaces and turbulent flows is here investigated numerically in a turbulent channel flow configuration at $Re_\tau \approx 180$. We show that a filamentous bed of a given geometry can modify a turbulent flow very differently depending on the resonance frequency of the surface, which is determined by elasticity and mass of the filaments. Filaments having resonance frequencies lower than the main frequency content of the turbulent wall-shear stress conform to slowly traveling elongated streaky structures, since they are too slow to adapt to fluid forces of higher frequencies. On the other hand, a bed consisting of stiff and low-mass filaments has a high resonance frequency and shows local regions of increased permeability, which results in large entrainment and a vast increase in drag.