Numerical investigation of controlling interfacial instabilities in non-standard Hele-Shaw configurations
Liam C. Morrow, Timothy J. Moroney, Scott W. McCue

TL;DR
This paper uses numerical simulations to explore how altering Hele-Shaw cell geometries and injection strategies can control and reduce viscous fingering patterns, with implications for fluid interface stability.
Contribution
It introduces a comprehensive numerical study of non-standard Hele-Shaw configurations, demonstrating effective control of interfacial instabilities through geometry and injection rate modifications.
Findings
Tapered and rotating plates reduce viscous fingering.
Rotation can completely stabilize the interface.
Injection rate and geometry influence finger number and stability.
Abstract
Viscous fingering experiments in Hele-Shaw cells lead to striking pattern formations which have been the subject of intense focus among the physics and applied mathematics community for many years. In recent times, much attention has been devoted to devising strategies for controlling such patterns and reducing the growth of the interfacial fingers. We continue this research by reporting on numerical simulations, based on the level set method, of a generalised Hele-Shaw model for which the geometry of the Hele-Shaw cell is altered. First, we investigate how imposing constant and time-dependent injection rates in a Hele-Shaw cell that is either standard, tapered or rotating can be used to reduce the development of viscous fingering when an inviscid fluid is injected into a viscous fluid over a finite time period. We perform a series of numerical experiments comparing the effectiveness of…
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