TY - JOUR
T1 - Density functional and infrared spectroscopy studies of bonding and vibrations of NH species adsorbed on the Ru(001) surface
T2 - A reassignment of the bending mode band
AU - Staufer, Markus
AU - Neyman, Konstantin M.
AU - Jakob, Peter
AU - Nasluzov, Vladimir A.
AU - Menzel, Dietrich
AU - Rösch, Notker
N1 - Funding Information:
The authors thank C.R. Landis and R. Schuster for discussions and they are grateful to the Deutsche Forschungsgemeinschaft (SFB 338), to the Bayerischer Forschungsverbund Katalyse (FORKAT), to the Fonds der Chemischen Industrie and to the Volkswagen-Stiftung (Project 1/68 691) for financial support of this study.
PY - 1996/12/20
Y1 - 1996/12/20
N2 - The electron energy-loss feature at about 1350 cm-1 often observed on the Ru(001) surface (and on other transition-metal surfaces) with N-and H-containing adsorbates is commonly assigned to the bending mode of the adsorbed NH species. Since it is widely used in the literature as a fingerprint for tilted NH species adsorbed on metals, we have inspected this assignment with the help of density functional model cluster calculations and infrared spectroscopy experiments. Adsorption in three-fold hollow sites with the N-H axis oriented perpendicular to the surface is computed to be energetically favored. Consequently, the Ru-N-H bending mode is dipole-forbidden in this adsorption complex, but this mode should be dipole-allowed for the tilted NH moiety calculated to be weaker bound in the on-top position of Ru(001). The vibrational frequencies of the Ru-N-H bending mode for both conceivable structures of the adsorption complexes are calculated to be lower by more than 500 cm-1 than the experimental value assigned to this mode. Newly recorded infrared spectra of the reactive N+O+H(D)/Ru(001) system could easily have detected N-H (N-D) stretching modes of adsorbed NH (ND) species. However, no maxima were found in the region from 700 to 2000 cm-1 which can be related to adsorbed NH, in full agreement with the density functional cluster-model results. Therefore, the electron energy-loss feature at about 1350 cm-1 has to be due to a different NH-related surface species.
AB - The electron energy-loss feature at about 1350 cm-1 often observed on the Ru(001) surface (and on other transition-metal surfaces) with N-and H-containing adsorbates is commonly assigned to the bending mode of the adsorbed NH species. Since it is widely used in the literature as a fingerprint for tilted NH species adsorbed on metals, we have inspected this assignment with the help of density functional model cluster calculations and infrared spectroscopy experiments. Adsorption in three-fold hollow sites with the N-H axis oriented perpendicular to the surface is computed to be energetically favored. Consequently, the Ru-N-H bending mode is dipole-forbidden in this adsorption complex, but this mode should be dipole-allowed for the tilted NH moiety calculated to be weaker bound in the on-top position of Ru(001). The vibrational frequencies of the Ru-N-H bending mode for both conceivable structures of the adsorption complexes are calculated to be lower by more than 500 cm-1 than the experimental value assigned to this mode. Newly recorded infrared spectra of the reactive N+O+H(D)/Ru(001) system could easily have detected N-H (N-D) stretching modes of adsorbed NH (ND) species. However, no maxima were found in the region from 700 to 2000 cm-1 which can be related to adsorbed NH, in full agreement with the density functional cluster-model results. Therefore, the electron energy-loss feature at about 1350 cm-1 has to be due to a different NH-related surface species.
KW - Chemisorption
KW - Density functional calculations
KW - Electron energy loss spectroscopy
KW - Infrared absorption spectroscopy
KW - Low index single crystal surfaces
KW - Metallic surfaces
KW - Ruthenium
UR - http://www.scopus.com/inward/record.url?scp=0030399574&partnerID=8YFLogxK
U2 - 10.1016/S0039-6028(96)00895-3
DO - 10.1016/S0039-6028(96)00895-3
M3 - Article
AN - SCOPUS:0030399574
SN - 0039-6028
VL - 369
SP - 300
EP - 312
JO - Surface Science
JF - Surface Science
IS - 1-3
ER -