The liquid-vapour interface of chain molecules investigated using a density functional approach

A microscopic density functional theory is used to investigate the liquid-vapour interface of fluids composed of short linear chains. We analyse the structure of the interface and evaluate the dependence of the surface tension and of the interfacial width on the temperature. The difference in chain length leads to differences in the thermodynamic properties of the fluids. The liquid-phase parts of the interfacial profiles of shorter chains exhibit oscillations at low temperatures. These oscillations vanish for longer chains. The surface tension and the interfacial width at a given temperature are found to increase with the chain length. Both the surface tension and the interfacial width scale as power laws upon approaching the critical point with critical exponents characteristic of mean-field-type theories and with prefactors depending on the chain length only.