The potential (E)-dependent vibrational behavior of a saturated CO adlayer on Au-core Pd-shell nanoparticle film electrodes was investigated over a wide potential range, in acidic, neutral, and basic solutions, using in situ surface-enhanced Raman spectroscopy (SERS). Over the whole of the examined potential region (-1.5 to 0.55 V vs. NHE), the peak frequencies of both the C-OM and the Pd-COM band (here, M denotes the multiply-bonded configuration) displayed three distinct linear regions: dvc oM/dE decreased from -185-207 (from -1.5 to -1.2 V) to -83-84 cm-1/V (-1.2 to -0.15 V), and then to 43 cm-1/V (-0.2 to 0.55 V); on the other hand, dvpd coM/dE changed from -10 to -8 cm I/V (from -1.5 to -1.2 V) to ^-31 to -30 cm-1/V (-1.2 to -0.15 V), and then to -15 cm-1/V (-0.2 to 0.55 V). The simultaneously recorded cyclic voltammograms revealed that at E 〈 -1.2 V, a hydro- gen evolution reaction (HER) occurred. With the help of periodic density functional theory calcula- tions using two different (2 × 2)-3CO slab models with Pd(111), the unusually high dvc-oM/dE and the small dVPd-CoM/dE in the HER region were explained as being due to the conversion of COad from bridge to hollow sites, which was induced by the co-adsorbed hydrogen atoms formed from dissociated water at negative potentials.
