Surface Chemistry on Bimetallic Alloy Surfaces: Adsorption of Anions and Oxidation of CO on Pt3Sn(111)
- 5 February 2003
- journal article
- research article
- Published by American Chemical Society (ACS) in Journal of the American Chemical Society
- Vol. 125 (9), 2736-2745
- https://doi.org/10.1021/ja028771l
Abstract
The microscopic structure of the Pt(3)Sn(111) surface in an electrochemical environment has been studied by a combination of ex situ low-energy electron diffraction (LEED), Auger electron spectroscopy (AES), and low-energy ion scattering (LEIS) and in situ surface X-ray scattering (SXS) and Fourier transform infrared (FTIR) spectroscopy. In ultrahigh vacuum (UHV) the clean-annealed surface produces a p(2 x 2) LEED pattern consistent with the surface composition, determined by LEIS, of 25 at. % Sn. SXS results show that the p(2 x 2) structure can be "transferred" from UHV into 0.5 M H(2)SO(4) and that the surface structure remains stable from 0.05 to 0.8 V. At 0.05 V the expansion of Pt surface atoms, ca. +2% from the bulk lattice spacing, is induced by adsorption of underpotential-deposited (UPD) hydrogen. At 0.5 V, where Pt atoms are covered by (bi)sulfate anions, the topmost layer is contracted relative to 0.05 V, although Sn atoms expand significantly, ca. 8.5%. The p(2 x 2) structure is stable even in solutions containing CO. In contrast to the Pt(111)-CO system, no ordered structures of CO are formed on the Pt(3)Sn(111) surface and the topmost layer expands relatively little (ca. 1.5%) from the bulk lattice spacing upon the adsorption of CO. The binding site geometry of CO on Pt(3)Sn(111) is determined by FTIR. In contrast to the near invariant band shape of a-top CO on Pt(111), changes in band morphology (splitting of the band) and vibrational properties (increase in the frequency mode) are clearly visible on the Pt(3)Sn(111) surface. To explain the line shape of the CO bands, we suggest that in addition to alloying effects other factors, such as intermolecular repulsion between coadsorbed CO and OH species, are controlling segregation of CO into cluster domains where the local CO coverage is different from the coverage expected for the CO-CO interaction on an unmodified Pt(111) surface.Keywords
This publication has 41 references indexed in Scilit:
- Surface processes and electrocatalysis on the Pt(hkl)/Bi-solution interfacePhysical Chemistry Chemical Physics, 2001
- Adsorption of Bisulfate and Sulfate Anions on a Pt(111) ElectrodeThe Journal of Physical Chemistry B, 2001
- Underpotential deposition of lead onto Pt(100) in acid solutions: Adsorption isotherms and interface structuresJournal of the Chemical Society, Faraday Transactions, 1998
- Surface Structure and Relaxation at the Pt(110)/Electrolyte InterfacePhysical Review Letters, 1996
- Dipole–dipole coupling effects upon infrared spectroscopy of compressed electrochemical adlayers: Application to the Pt(111)/CO systemThe Journal of Chemical Physics, 1995
- Copper Electrodeposition on Pt(111) in the Presence of Chloride and (Bi)sulfate: Rotating Ring-Pt(111) Disk Electrode StudiesLangmuir, 1995
- Vibrational spectroscopy of adsorbed sulfate on Pt(111)Electrochimica Acta, 1994
- Potential dependent surface relaxation of the Pt(001)/electrolyte interfacePhysical Review Letters, 1993
- Atomic structure at electrode interfacesSynchrotron Radiation News, 1993
- Effect of anions on the underpotential deposition of copper on platinum(111) and platinum(100) surfacesLangmuir, 1993