In-plane structure of the liquid–vapor interfaces of dilute bismuth:gallium alloys: X-ray-scattering studies

Abstract

The in-plane structure functions in the liquid–vapor interfaces of two bismuth–gallium alloys (0.18 at. % Bi and 0.07 at. % Bi) have been studied by grazing incidence x-ray diffraction. The higher concentration alloy exhibits, at 25, 43, and 77 °C, segregation of Bi into nearly complete monolayers atop the bulk alloy; at each temperature the Bi monolayer has the structure of a two-dimensional supercooled liquid. The intensity distribution of the diffuse x-ray scattering at qz=1.0 and 1.5 Å−1 is used to calculate the surface tension of the alloy at 77 °C; the value obtained is 570±30 dyn/cm. This value, which is very different from the value obtained by extrapolating the surface tension of liquid Bi to 77 °C, is related to the structure of the liquid–vapor interface. We have compared experimental grazing incidence x-ray diffraction studies on the liquid–vapor interface of the 0.07% alloy with integral-equation theoretical calculations on a two-dimensional hard-disk fluid mixture. The results suggest that the segregated partial monolayer may consist of dimers and trimers in equilibrium with a small amount of two-dimensional liquid bismuth.