Coadsorption of n-Propanol and Water on SiO2: Study of Thickness, Composition, and Structure of Binary Adsorbate Layer Using Attenuated Total Reflection Infrared (ATR-IR) and Sum Frequency Generation (SFG) Vibration Spectroscopy

Abstract

The thickness and structure of the binary adsorbate layer of n-propanol and water molecules formed on fused silica at near equilibrium vapor pressure at room temperature were studied using attenuated total reflectance infrared spectroscopy (ATR-IR) and sum frequency generation (SFG) vibration spectroscopy. The thickness of the binary adsorbate layer on silica is kept relatively constant at ∼0.9 nm when the n-propanol vapor fraction (ypropanol) is between 0.6 and 1 and then gradually increases up to ∼6.5 nm as ypropanol decreases from 0.6 to 0 (ywater increasing from 0.4 to 1). The composition of the binary adsorbate layer as well as the n-propyl group at the adsorbate/air interface shows a drastic change at the azeotrope composition of the vapor mixture (ypropanol = 0.36). The binary mixture is propanol-rich at ypropanol > 0.36 and water-rich at ypropanol < 0.36, which is consistent with the vapor–liquid equilibrium. However, the vapor composition dependence of the adsorbate/air interface structure appears drastically different from that of the liquid/air interface. The n-propanol SFG signal at the adsorbate/air interface gradually decreases as ypropanol decreases from 1 and suddenly drops at ypropanol = 0.36, while the n-propanol SFG signal increases to a maximum value at ypropanol = 0.36 for the liquid/air interface. Comparison of the ATR-IR and SFG results suggests that the binary adsorbate layer of n-propanol and water assumes a layered structure in which n-propanol is at the adsorbate/vapor interface and water is inside the adsorbate layer, and unlike the liquid/vapor interface, the propanol molecules do not form a paired dimer-like structure at the adsorbate/vapor interface.