Early Transient Period in the Evolution of the Area of a Passive Front Propagating in a Strong Turbulence

Abstract

Influence of statistically stationary, homogeneous, and isotropic turbulence on the mean area of a passive self-propagating front and, hence, on the rate of fluid consumption by the front is analysed in the case of asymptotically high turbulent Reynolds number ReL and asymptotically high ratio of the Kolmogorov velocity to a constant speed u0 of the front. By considering an early stage of the front evolution, the mean (over the studied early stage) front area and consumption velocity uT are analytically determined. The analysis shows that the mean uT is proportional to the rms turbulent velocity, which characterizes large-scale turbulent eddies, even if the instantaneous rate of an increase in the front area is mainly controlled by the smallest Kolmogorov eddies. A straightforward dependence of the mean area or uT on the Kolmogorov velocity, length, and time scales vanishes due to the following physical mechanism. At high ReL, turbulent stretching created by small-scale eddies increases the front area exponentially with time, whereas a volume bounded by the leading and trailing edges of the front grows significantly slower. Therefore, after a short time, the volume is tightly filled by the front and the mean distance between opposed front elements becomes small with respect to Kolmogorov length scale. Subsequently, such front elements collide, thus, reducing the front area and limiting the mean uT.