TY - JOUR
T1 - Toward a chemisorption cluster model using the LCGTO‐Xα method
T2 - Application to Ni(100)/Na
AU - Rösch, N.
AU - Sandl, P.
AU - Görling, A.
AU - Knappe, P.
PY - 1988
Y1 - 1988
N2 - A modified cluster approach for modeling local chemisorption phenomena is suggested on the basis of the linear combination of Gaussian‐type orbitals (LCGTO) Xα method. Contractions of the fitting bases are employed to take into account the reduced polarizability of a surface cluster and to access larger cluster sizes. Furthermore, embedding of a cluster in the surface is mimicked by Gaussian broadening of the one‐electron levels leading to fractional occupation numbers via a self‐consistently determined Fermi energy of the cluster. As a first application results are presented for the clusters NinNa (n = 5, 9, 17) modeling the low coverage limit of the chemisorption system Ni(100)/Na. Calculated bond length, binding energy, and induced “surface” dipole moment show fair agreement with experimental values, indicating a substantial covalent character of alkali bonding on transition metal surfaces even in the zero coverage limit.
AB - A modified cluster approach for modeling local chemisorption phenomena is suggested on the basis of the linear combination of Gaussian‐type orbitals (LCGTO) Xα method. Contractions of the fitting bases are employed to take into account the reduced polarizability of a surface cluster and to access larger cluster sizes. Furthermore, embedding of a cluster in the surface is mimicked by Gaussian broadening of the one‐electron levels leading to fractional occupation numbers via a self‐consistently determined Fermi energy of the cluster. As a first application results are presented for the clusters NinNa (n = 5, 9, 17) modeling the low coverage limit of the chemisorption system Ni(100)/Na. Calculated bond length, binding energy, and induced “surface” dipole moment show fair agreement with experimental values, indicating a substantial covalent character of alkali bonding on transition metal surfaces even in the zero coverage limit.
UR - http://www.scopus.com/inward/record.url?scp=84990678059&partnerID=8YFLogxK
U2 - 10.1002/qua.560340832
DO - 10.1002/qua.560340832
M3 - Article
AN - SCOPUS:84990678059
SN - 0020-7608
VL - 34
SP - 275
EP - 285
JO - International Journal of Quantum Chemistry
JF - International Journal of Quantum Chemistry
IS - 22 S
ER -