The aim of this work is to characterize the thermodynamic state of fuel mixed into the turbulent flame brush in the context of the Zel'dovich deflagration-to-detonation transition (ZDDT) mechanism of Type Ia supernovae (SNe Ia). We perform a series of three-dimensional computer simulations of thermonuclear deflagrations subject to the Rayleigh-Taylor instability (RTI) for conditions found in model explosions of centrally ignited realistic, Chandrasekhar mass white dwarf progenitors. These conditions correspond to explosion times when the flame reaches low density progenitor regions where DDT is expected to occur. The flame database is constructed using a thickened flame model. High numerical resolution is achieved with the help of the adaptive mesh refinement (AMR) approach allowing, for the first time, to resolve mesoscale buoyancy-driven flame turbulence. The system is evolved to a quasi-steady state, and flow properties in the turbulent region, where turbulence is most isotropic, is analyzed in a co-moving frame of reference. We find evidence for strong buoyancy-driven adiabatic heating of fuel layers adjacent to the flame front. The heating results in a dramatic reduction of fuel ignition times by between $\approx$2 and more than about 5 orders of magnitude. The heating increases with the RTI forcing. The observed shortening of fuel burning timescales suggests a new source of energy is important inside fuel penetrating the flame brush. These regions are up to several hundred meters wide. On the basis of the previous results of turbulent combustion in SNe Ia, preconditioning required by the ZDDT mechanism can occur there.
Comment: 17 pages, 12 figures, submitted to MNRAS