F. Rittner et al., Adsorption of nitrogen on rutile(110). 2. Construction of a full five-dimensional potential energy surface, LANGMUIR, 15(4), 1999, pp. 1449-1455
A full five-dimensional potential energy surface for the interaction of nit
rogen molecules with the (110) surface plane of TiO2 (rutile) is generated.
In a first step, ab initio SCF cluster calculations are performed for vari
ous adsorption geometries of N-2 above the TiO2(110) surface, which is desc
ribed by different stoichiometric clusters, ranging in composition from Ti7
O14 to Ti13O26, embedded in extended point charge fields. The N-N distance
is fixed to the experimental equilibrium bond length 1.098 Angstrom. In a s
econd step, a simple analytic form for the interaction potential is develop
ed which contains the electrostatic interaction between the charge distribu
tion of N-2 and the electric field above the surface, the polarization of t
he N-2 molecule by this field, and the Pauli repulsion between N-2 and the
surface. By fitting the five parameters in the analytic expression (quadrup
ole moment and the two polarizability components of N-2, repulsive Lennard-
Jones parameters between N and the O and Ti atoms of the surface) to the ca
lculated ab initio interaction energies, one can represent the full five-di
mensional interaction potential with a mean error of about 3 kcal/mol. The
global minimum of the interaction potential is found for the vertical end-o
n adsorption of N-2 on a coordinately unsaturated row A titanium atom; it h
as an adsorption energy of -46 kJ/mol and a Ti-N distance of 2.39 Angstrom.
The side-on adsorption of N-2 on the row B oxygen atoms with the N-N axis
perpendicular to the row B direction is also slightly attractive with a sma
ll adsorption energy of -5.5 kJ/mol.