Rods are less fragile than spheres: Structural relaxation in dense liquids composed of anisotropic particles

Abstract

We perform extensive molecular dynamics simulations of dense liquids composed of bidisperse dimer- and ellipse-shaped particles in 2D that interact via repulsive contact forces. We measure the structural relaxation times obtained from the long-time decay of the self-part of the intermediate scattering function for the translational and rotational degrees of freedom (DOF) as a function of packing fraction φ, temperature T, and aspect ratio α. We are able to collapse the φ and T-dependent structural relaxation times for disks, and dimers and ellipses over a wide range of α, onto a universal scaling function F(|φ-φ0|,T,α), which is similar to that employed in previous studies of dense liquids composed of purely repulsive spherical particles in 3D. F for both the translational and rotational DOF are characterized by the α-dependent scaling exponents μ and δ and packing fraction φ0(α) that signals the crossover in the scaling form F from hard-particle dynamics to super-Arrhenius behavior for each aspect ratio. We find that the fragility at φ0, m(φ0), decreases monotonically with increasing aspect ratio for both ellipses and dimers. Moreover, the results for the slow dynamics of dense liquids composed of dimer- and ellipse-shaped particles are qualitatively the same, despite the fact that zero-temperature static packings of dimers are isostatic, while static packings of ellipses are hypostatic.