Flame dynamics and Markstein numbers in Hele-Shaw cells and porous media under Darcy's law

TL;DR

This paper develops a hydrodynamic model for premixed flames in Hele-Shaw cells and porous media under Darcy's law, revealing unique Markstein numbers and confinement effects on flame stability and instabilities.

Contribution

It introduces a Darcy-specific hydrodynamic model showing that Markstein numbers differ and new effects emerge, especially under confinement, altering flame instability dynamics.

Findings

Markstein numbers $ ext{M}_c$ and $ ext{M}_t$ are unequal under Darcy's law.

Confinement influences hydrodynamic instabilities, amplifying Darrieus--Landau instability.

Different nonlinear regimes (Michelson--Sivashinsky, Ginzburg--Landau) are identified depending on confinement strength.

Abstract

The propagation of premixed flames in narrow Hele-Shaw cells and permeable porous media is governed by Darcy's law, leading to hydrodynamic behaviour distinct from conventional flames. This study investigates the role of confinement on flame dynamics, focusing on the associated Markstein numbers. A hydrodynamic model treating the flame as a discontinuity surface is presented, in which the burning rate depends on curvature and tangential flow strain, characterised by two Markstein numbers $\mathcal{M}_c$ and $\mathcal{M}_t$. A major finding is that $\mathcal{M}_c \neq \mathcal{M}_t$ under Darcy's law, as the law permits tangential velocity discontinuities at the flame front due to viscosity variations. Additionally, a third Markstein number $\mathcal{M}_g$ associated with gravity also emerges uniquely under Darcy's law. The Darcy-specific effects vanish in purely radial flows but are important for strained flames. In planar counterflows, for instance, the strain rate jump across the flame is dictated by the unburnt-to-burnt viscosity ratio $\mathfrak{m}$ rather than the density ratio $\mathfrak{r}$, a dramatic departure from conventional behaviour. The influence of confinement on the combined hydrodynamic instabilities of planar flames, namely Darrieus--Landau, Saffman--Taylor, and Rayleigh--Taylor instabilities, is discussed. Weakly nonlinear dynamics under strong confinement is found to follow a Michelson--Sivashinsky equation with modified coefficients (long-wave instability), while under moderate confinement, Ginzburg--Landau dynamics (finite-wavenumber instability) is found to apply. Strong confinement amplifies the Darrieus--Landau instability, enhancing hydrodynamic coupling in conjunction with augmented streamline refraction caused by tangential velocity discontinuities.