TY - JOUR
T1 - Tungsten atoms and clusters adsorbed on the MgO(001) surface
T2 - A density functional study
AU - Cai, Shuhui
AU - Neyman, Konstantin M.
AU - Hu, Anguang
AU - Rösch, Notker
PY - 2000/12/7
Y1 - 2000/12/7
N2 - Adsorption of tungsten clusters Wn (n = 1-4) on the ideal MgO(001) surface has been studied computationally using a scalar relativistic density functional method and a gradient-corrected exchange-correlation functional. Structure and energetic features of the adsorption complexes Wn/MgO(001) have been analyzed. The oxide surface was represented by cluster models embedded in a large array of point charges (PCs). To reduce the artificial polarization of oxygen anions in the immediate vicinity of positive PCs, the cations at the cluster boundaries were treated as Mg2+ ions at either all-electron or pseudopotential (PP) level. Compared to the all-electron + PC embedding, the significantly more economic PP + PC approach is demonstrated to impose cluster model boundary conditions appropriate to the ionic oxide MgO. The cluster size dependence of the adsorption properties is found weak. Like other transition metal clusters considered previously, tungsten species favor adsorption sites in the proximity of oxygen centers of MgO(001). Rather small calculated adsorptioninduced deformations of the tungsten clusters manifest notably stronger W-W bonds compared to W-O bonds between metal and substrate. The tetrahedron shape of W4, most stable in the gas phase, is calculated to be energetically preferred also in the adsorbed state, in particular over a square-planar adsorbate. This finding is at variance with a model of two-dimensional W4 clusters on MgO(001) derived from a recent high-resolution electron microscopy investigation (Tanaka, N., et al. Surf. Rev. Lett. 1998, 5, 723). The configuration of W3 with two W atoms located close to two nearest-neighbor oxygen ions is favored over that where two W atoms are close to next-nearest-neighbor substrate anions. In both cases, the adsorbed W3 cluster tilts considerably from an upright orientation.
AB - Adsorption of tungsten clusters Wn (n = 1-4) on the ideal MgO(001) surface has been studied computationally using a scalar relativistic density functional method and a gradient-corrected exchange-correlation functional. Structure and energetic features of the adsorption complexes Wn/MgO(001) have been analyzed. The oxide surface was represented by cluster models embedded in a large array of point charges (PCs). To reduce the artificial polarization of oxygen anions in the immediate vicinity of positive PCs, the cations at the cluster boundaries were treated as Mg2+ ions at either all-electron or pseudopotential (PP) level. Compared to the all-electron + PC embedding, the significantly more economic PP + PC approach is demonstrated to impose cluster model boundary conditions appropriate to the ionic oxide MgO. The cluster size dependence of the adsorption properties is found weak. Like other transition metal clusters considered previously, tungsten species favor adsorption sites in the proximity of oxygen centers of MgO(001). Rather small calculated adsorptioninduced deformations of the tungsten clusters manifest notably stronger W-W bonds compared to W-O bonds between metal and substrate. The tetrahedron shape of W4, most stable in the gas phase, is calculated to be energetically preferred also in the adsorbed state, in particular over a square-planar adsorbate. This finding is at variance with a model of two-dimensional W4 clusters on MgO(001) derived from a recent high-resolution electron microscopy investigation (Tanaka, N., et al. Surf. Rev. Lett. 1998, 5, 723). The configuration of W3 with two W atoms located close to two nearest-neighbor oxygen ions is favored over that where two W atoms are close to next-nearest-neighbor substrate anions. In both cases, the adsorbed W3 cluster tilts considerably from an upright orientation.
UR - http://www.scopus.com/inward/record.url?scp=0034516403&partnerID=8YFLogxK
U2 - 10.1021/jp002538x
DO - 10.1021/jp002538x
M3 - Article
AN - SCOPUS:0034516403
SN - 1520-6106
VL - 104
SP - 11506
EP - 11514
JO - Journal of Physical Chemistry B
JF - Journal of Physical Chemistry B
IS - 48
ER -