Morphology of Flow Patterns Generated by Viscous Fingering from Miscible Fluids

TL;DR

This paper explores the complex flow patterns formed by viscous fingering in miscible fluids within porous media, using differential geometry to analyze their morphology and provide new insights into their structure.

Contribution

It introduces a geometric approach to study viscous fingering patterns, connecting differential geometry concepts with flow morphology analysis.

Findings

Viscous fingering patterns can be characterized by geometric surfaces and curves.

Differential geometry provides a useful framework for analyzing flow pattern morphology.

The approach offers new perspectives for understanding flow instabilities in miscible fluids.

Abstract

A rest fluid displaced by a less viscous fluid in a porous medium triggers the so-called Saffman-Taylor instability at their contact front and hence forms complicated finger-like patterns. When the two fluids are miscible, the surface tension at their contact front vanishes, leaving the variation in viscosity dominant the contribution to the instability. The phenomena, named viscous fingering, can be studied by the analogy of a single-phase flow in the Hele-Shaw cell, a quasi-two-dimensional rectilinear plane. Viscous fingering produces complex geometrical patterns. They are important not only in industry but also in mathematics. Theoretical analyses on the evolution of the finger-like patterns in miscible fluids are still expanding (it is referred to the morphology of the flow patterns). Here we study the morphology of the finger-like patterns within some simple concepts in differential geometry, in which surfaces and curves are analog to the profiles of the concentration and its contours, respectively. We thus can investigate the fingering phenomena through the geometrical perspective in which various results in differential geometry are immediately applicable.