Normal mode analysis of liquid CS2: Velocity correlation functions and self-diffusion constants

Abstract

Normal mode analysis (NMA) is applied in a molecular‐dynamics simulation of liquid CS₂, modeled with a potential including internal degrees of freedom. The entire supercooled liquid range, from the glass transition at 100 K to melting at 165 K, and the normal liquid from 165 to 293 K, are studied at P=1 atm. The normal modes of the liquid are classified as translation parallel (trans‐∥) and perpendicular (trans‐⊥) to the molecular axis, rotation, symmetric stretch, antisymmetric stretch, and bend. The configuration‐averaged density of states, 〈ρ(ω)〉, with both stable and unstable modes, is correspondingly decomposed into separate contributions 〈ρ^γ(ω)〉, with γ=trans‐∥, etc. The trans‐∥, trans‐⊥, and rotational velocity correlation functions, and diffusion constants D^γ, are shown to be calculable from the same NMA techniques previously developed for atoms, so long as the appropriate 〈ρ^γ(ω)〉 is used. Agreement between NMA theory and simulation is extremely good for the trans‐⊥ velocity correlation function and for the diffusion constants in the lower temperature range, is good for the trans‐∥ velocity correlation, and is fair for the rotational velocity correlation. Anharmonicities within wells of the many‐body potential are seen to be more important in CS₂ than in atomic liquids. At higher temperatures the rotational unstable modes,...