Applications of elastic instability and elastic turbulence: Review, limitations, and future directions

TL;DR

This review explores the applications, limitations, and future prospects of elastic instability and elastic turbulence in complex fluids, emphasizing their roles in microfluidics, heat transfer, and enhanced oil recovery.

Contribution

It provides a comprehensive synthesis of research on elastic instability and turbulence, focusing on their practical applications and future research directions.

Findings

Elastic instability can enhance microfluidic mixing.

Elastic turbulence improves microscale heat transfer.

Potential for elastic phenomena in oil recovery processes.

Abstract

Viscoelastic fluids are a subclass of complex fluids used in widespread applications ranging from biological to large-scale industrial settings. These fluids are often associated with various complex flow phenomena due to the presence of non-linear elastic stresses, originating due to the stretching and relaxation phenomena of microstructure (such as polymer molecules in the case of a viscoelastic polymer solution) in a deformed flow field. One such phenomenon is elastic instability (EI) which emerges due to the interaction between elastic stresses and streamline curvature present in a flow system at small values of the Renolds number (ratio of the inertial to that of the viscous forces) when the Weissenberg number (ratio of the microstructure relaxation time to that of the rate of flow deformation) exceeds a critical value. On further increasing this Weissenberg number to higher values, the unstable flow field caused due to this elastic instability transits to a more chaotic and turbulent-like flow structure called elastic turbulence (ET). Over the last two decades or so, an extensive investigation has been performed on this particular topic in the complex fluids research community. Some excellent articles recently present this ET phenomenon's development, understanding, and progress in the literature. This article focuses on the application perspectives of this phenomenon. In particular, this article aims to provide a comprehensive review of the investigations conducted so far in the literature to demonstrate the potential of these EI and ET phenomena in three main application areas, namely, microfluidic mixing, microscale heat transfer, and chemically enhanced oil recovery (EOR) process. Additionally, a detailed discussion of the limitations and future directions of these EI and ET phenomena from an application point of view is also presented in this article.