We present and discuss here results concerning the implementation of molecular dynamics simulations with the Green-Kubo formalism to predict transport coefficients in SF 6 /N 2 mixtures under conditions of practical interest. SF 6 was modeled using a flexible molecular force field recently proposed [Olivet, A.; Vega, L. F. J. Chem. Phys. 2007, 126, 144502], while the force field of Galassi and Tildesley was used for N 2 modeling [Galassi, G.; Tildesley, D. J. Mol. Simul. 1994, 13, 11]. The influence of mixture composition on the mutual diffusion coefficients and shear viscosities was investigated by a series of molecular dynamic simulations of SF 6 /N 2 mixtures with different compositions at 300 K and 1 MPa. Temperature and pressure dependencies of the mutual diffusion coefficient were also investigated for a fixed composition of SF 6 /N 2 , covering the temperature range from 260 to 340 K and two pressure values (1 and 2 MPa). Simulations with these anisotropic force fields led to mutual diffusion coefficients that diminish when the SF 6 concentration in the mixture is increased. This behavior differs from the hypothesis of no composition dependence assumed for several estimation methods available in the literature for gaseous binary mixtures at low pressures. Such a composition dependence is explained on the basis of the deviations from ideality of SF 6 /N 2 mixtures. The effect of the molecular flexibility considered in the SF 6 molecular model is analyzed by comparing the transport coefficients estimated with the aforementioned force fields to those estimated with simple Lennard-Jones potentials. Differences between predictions with the anisotropic force fields and the simpler Lennard-Jones potentials were more significant in the case of the shear viscosity; while viscosities estimated with the Lennard-Jones potentials showed no dependence on composition, the estimations based on the anisotropic force fields exhibited a maximum value for the viscosity, which is the same behavior described by an empirical method. Results presented here are pure predictions, thus covering part of the lack of information existing about the transport coefficients of these mixtures, which is of relevance for several industrial processes.