Coupling/decoupling between translational and rotational dynamics in a supercooled molecular liquid

Abstract

We use molecular dynamics computer simulations to investigate the coupling/decoupling between translational and rotational dynamics in a glass-forming liquid of dumbbells. This is done via a careful analysis of the α-relaxation time τq* C of the incoherent center-of-mass density correlator at the structure factor peak, the α-relaxation time τ2 of the reorientational correlator, and the translational (Dt) and rotational (Dr) diffusion constants. We find that the coupling between the relaxation times τq* C and τ2 increases with decreasing temperature T, whereas the coupling decreases between the diffusivities Dt and Dr. In addition, the T-dependence of Dt decouples from that of 1/τ2, which is consistent with previous experiments and has been interpreted as a signature of the "translation-rotation decoupling." We trace back these apparently contradicting observations to the dynamical heterogeneities in the system. We show that the decreasing coupling in the diffusivities Dt and Dr is only apparent due to the inadequacy of the concept of the rotational diffusion constant for describing the reorientational dynamics in the supercooled state. We also argue that the coupling between τq* C and τ2 and the decoupling between Dt and 1/τ2, both of which strengthen upon cooling, can be consistently understood in terms of the growing dynamic length scale.