Turbulent Flame Speed Scaling for Expanding Flames with Markstein Diffusion Considerations

Abstract

In this work we clarify the role of Markstein diffusivity on turbulent flame speed and it's scaling, from analysis and experimental measurements on constant-pressure expanding flames propagating in near isotropic turbulence. For all C0-C4 hydrocarbon-air mixtures presented in this work and recently published C8 data from Leeds, the normalized turbulent flame speed data of individual mixtures approximately follows the recent theoretical and experimental ReT,f0.5 scaling, where the average radius is the length scale and thermal diffusivity is the transport property. We observe that for a constant ReT,f , the normalized turbulent flame speed decreases with increasing Markstein Number. This could be explained by considering Markstein diffusivity as the large wavenumber, flame surface fluctuation dissipation mechanism. As originally suggested by the theory, replacing thermal diffusivity with Markstein diffusivity in the turbulence Reynolds number definition above, the present and Leeds dataset could be scaled by the new ReT,M0.5 irrespective of the fuel considered, equivalence ratio, pressure and turbulence intensity for positive Mk flames over a large range of Damk\"ohler numbers.