INFRARED SPECTROSCOPY OF MODEL ELECTROCHEMICAL INTERFACES IN ULTRAHIGH VACUUM - SOME IMPLICATIONS FOR IONIC AND CHEMISORBATE SOLVATION AT ELECTRODE SURFACES

摘要

The utility of infrared reflection-absorption spectroscopy (IRAS) for examining structure and bonding for model electrochemical interfaces in ultrahigh vacuum (UHV) is illustrated, focusing specifically on the solvation of cations and chemisorbed carbon monoxide on Pt(111). These systems were chosen partly in view of the availability of IRAS data (albeit limited to chemisorbate vibrations) for the corresponding in-situ metal-solution interfaces, enabling direct spectral comparisons to be made with the ''UHV electrochemical model'' systems. Kelvin probe measurements of the metal-UHV surface potential changes (Delta phi) attending alterations in the interfacial composition are also described: these provide the required link to the in-situ electrode potentials as well as yielding additional insight into surface solvation. Variations in the negative electronic charge density and, correspondingly, in the cation surface concentration (thereby mimicking charge-induced alterations in the electrode potential below the potential of-zero charge) are achieved by potassium atom dosage onto Pt(111). Of the solvents selected for discussion here - deuterated water, methanol, and acetonitrile - the first two exhibit readily detectable vibrational bands which provide information on the ionic solvation structure. Progressively dosing these solvents onto Pt(111) in the presence of low potassium coverages yields marked alterations in the solvent vibrational bands which can be understood in terms of sequential cation solvation. Comparison between these spectra for methanol with analogous data for sequential methanol solvation of gas-phase alkali cations enables the influence of the interfacial environment to be assessed. The effects of solvating chemisorbed CO are illustrated for acetonitrile; the markedly larger shifts in CO frequencies and binding sites for dilute CO adlayers can be accounted for in terms of short-range coadsorbate interactions in addition to longer-range Stark effects. The differing degrees of selective solvation of cations versus CO for water and acetonitrile are also explored. While the former solvent removes all specific effects of K+ upon CO, these short-range interactions partly remain upon acetonitrile solvation. The close connections between the UHV-based findings and the behavior of the in-situ electrochemical systems are also discussed. References: 49