Turbulence-assisted formation of bacterial cellulose

TL;DR

This study investigates how controlled turbulent flows at the air-liquid interface influence bacterial cellulose structure, offering new methods to engineer biomaterials through turbulence manipulation.

Contribution

It demonstrates that two-dimensional turbulence can induce chaotic rotation and stretching, providing a novel approach to control bacterial cellulose formation.

Findings

Turbulence causes chaotic fluid motion at the interface.

Turbulence induces persistent stretching of fluid elements.

Potential to engineer cellulose structure by adjusting turbulence parameters.

Abstract

Bacterial cellulose is an important class of biomaterials which can be grown in well-controlled laboratory and industrial conditions. The cellulose structure is affected by several biological, chemical and environmental factors, including hydrodynamic flows in bacterial suspensions. In this work, we explore the possibility of using well controlled turbulent flow to control the bacterial cellulose production. Turbulent flows leading to random motion of fluid elements may affect the structure of the extracellular polymeric matrix produced by bacteria. Here we show that two-dimensional turbulence at the air-liquid interface generates chaotic rotation at a well-defined scale and random persistent stretching of the fluid elements. The results offer new approaches to engineering of the bacterial cellulose structure by controlling turbulence parameters.