Fronts in randomly advected and heterogeneous media and nonuniversality of Burgers turbulence: Theory and numerics

TL;DR

This paper establishes a theoretical and numerical framework linking Burgers turbulence with Huygens fronts in heterogeneous media, revealing nonuniversal, forcing-dependent properties relevant to combustion modeling.

Contribution

It provides systematic upper bounds on Burgers turbulence energy density using the replica method, highlighting nonuniversality and spectrum dependence of front speedup.

Findings

Upper bounds on Burgers energy density are within 15% of simulations.

Burning velocity does not diverge with increasing Reynolds number.

Numerical results confirm the spectrum dependence of front speedup.

Abstract

A recently established mathematical equivalence--between weakly perturbed Huygens fronts (e.g., flames in weak turbulence or geometrical-optics wave fronts in slightly nonuniform media) and the inviscid limit of white-noise-driven Burgers turbulence--motivates theoretical and numerical estimates of Burgers-turbulence properties for specific types of white-in-time forcing. Existing mathematical relations between Burgers turbulence and the statistical mechanics of directed polymers, allowing use of the replica method, are exploited to obtain systematic upper bounds on the Burgers energy density, corresponding to the ground-state binding energy of the directed polymer and the speedup of the Huygens front. The results are complementary to previous studies of both Burgers turbulence and directed polymers, which have focused on universal scaling properties instead of forcing-dependent parameters. The upper-bound formula can be heuristically understood in terms of renormalization of a different kind from that previously used in combustion models, and also shows that the burning velocity of an idealized turbulent flame does not diverge with increasing Reynolds number at fixed turbulence intensity, a conclusion that applies even to strong turbulence. Numerical simulations of the one-dimensional inviscid Burgers equation using a Lagrangian finite-element method confirm that the theoretical upper bounds are sharp within about 15% for various forcing spectra (corresponding to various two-dimensional random media). These computations provide a new quantitative test of the replica method. The inferred nonuniversality (spectrum dependence) of the front speedup is of direct importance for combustion modeling.