Asymptotics for turbulent flame speeds of the viscous G-equation enhanced by cellular and shear flows

Abstract

G-equations are well-known front propagation models in turbulent combustion and describe the front motion law in the form of local normal velocity equal to a constant (laminar speed) plus the normal projection of fluid velocity. In level set formulation, G-equations are Hamilton-Jacobi equations with convex (L1 type) but non-coercive Hamiltonians. Viscous G-equations arise from either numerical approximations or regularizations by small diffusion. The nonlinear eigenvalue H from the cell problem of the viscous G-equation can be viewed as an approximation of the inviscid turbulent flame speed sT. An important problem in turbulent combustion theory is to study properties of sT, in particular how sT depends on the flow amplitude A. In this paper, we will study the behavior of H= H(A,d) as A +∞ at any fixed diffusion constant d > 0. For the cellular flow, we show that H(A,d)≤ O( logA) for all d>0. Compared with the inviscid G-equation (d=0), the diffusion dramatically slows down the front propagation. For the shear flow, the limit A +∞ H(A,d) A = λ (d) >0 where λ (d) is strictly decreasing in d, and has zero derivative at d=0. The linear growth law is also valid for sT of the curvature dependent G-equation in shear flows.