Diffusive-thermal instabilities of a planar premixed flame aligned with a shear flow

TL;DR

This paper investigates the stability of a planar premixed flame under shear flow, revealing how shear-enhanced diffusion influences classical flame instabilities and identifying new bifurcation behaviors through analytical and numerical methods.

Contribution

It provides a novel analytical dispersion relation linking shear effects to flame instabilities and demonstrates the existence of new bifurcation types depending on flow parameters.

Findings

Classical cellular instability occurs for Le>1 when Peclet number exceeds a critical value.

Type-II_s bifurcation leads to Kuramoto--Sivashinsky dynamics in weakly nonlinear regime.

Oscillatory instability is suppressed at high Peclet numbers.

Abstract

The stability of a thick planar premixed flame, propagating steadily in a direction transverse to that of unidirectional shear flow, is studied. A linear stability analysis is carried out in the asymptotic limit of infinitely large activation energy, yielding a dispersion relation. The relation characterises the coupling between Taylor dispersion (or shear-enhanced diffusion) and the flame thermo-diffusive instabilities, in terms of two main parameters, namely, the reactant Lewis number $Le$ and the flow Peclet number $Pe$. The implications of the dispersion relation are discussed and various flame instabilities are identified and classified in the $Le$-$Pe$ plane. An important original finding is the demonstration that for values of the Peclet number exceeding a critical value, the classical cellular instability, commonly found for $Le<1$, exists now for $Le>1$ but is absent when $Le<1$. In fact, the cellular instability identified for $Le>1$ is shown to occur either through a finite-wavelength stationary bifurcation (also known as type-I$_s$) or through a longwave stationary bifurcation (also known as type-II$_s$). The latter type-II$_s$ bifurcation leads in the weakly nonlinear regime to a Kuramoto--Sivashinsky equation, which is determined. As for the oscillatory instability, usually encountered in the absence of Taylor dispersion in $Le>1$ mixtures, it is found to be absent if the Peclet number is large enough. The stability findings, which follow from the dispersion relation derived analytically, are complemented and examined numerically for a finite value of the Zeldovich number. The numerical study involves both computations of the eigenvalues of a linear stability boundary-value problem and numerical simulations of the time-dependent governing partial differential equations. The computations are found to be in good qualitative agreement with the analytical predictions.