Nonlinear Dynamics of a Viscous Bubbly Fluid

TL;DR

This paper develops a comprehensive nonlinear model for viscous bubbly fluids, analyzing equilibrium and wave solutions, and deriving simplified PDEs that connect to classical equations like Burgers and KdV, with applications to volcanic flows.

Contribution

It introduces a detailed physical and mathematical model for viscous bubbly fluids, including exact and approximate solutions, and links to well-known nonlinear PDEs, advancing understanding of complex fluid dynamics in geological contexts.

Findings

Exact solutions for equilibrium and traveling waves identified.

Approximate solutions relate to classical nonlinear PDEs such as Burgers and KdV.

Dimensionless parameters estimated for magma flow scenarios.

Abstract

A physical model of a three-dimensional flow of a viscous bubbly fluid in an intermediate regime between bubble formation and breakage is presented. The model is based on mechanics and thermodynamics of a single bubble coupled to the dynamics of a viscous fluid as a whole, and takes into account multiple physical effects, including gravity, viscosity, and surface tension. Dimensionless versions of the resulting nonlinear model are obtained, and values of dimensionless parameters are estimated for typical magma flows in horizontal subaerial lava fields and vertical volcanic conduits. Exact solutions of the resulting system of nonlinear equations corresponding to equilibrium flows and traveling waves are analyzed in the one-dimensional setting. Generalized Su-Gardner-type perturbation analysis is employed to study approximate solutions of the model in the long-wave ansatz. Simplified nonlinear partial differential equations (PDE) satisfied by the leading terms of the perturbation solutions are systematically derived. It is shown that for specific classes of perturbations, approximate solutions of the bubbly fluid model arise from solutions of the classical diffusion, Burgers, variable-coefficient Burgers, and Korteweg-de Vries equations.