Abstract :
The ZnO surfaces, apart from their role in catalytic processes, raise fundamental questions regarding the key parameters,
which stabilise ionic material surfaces. The ZnO structure consists of hexagonal planes stacked with the sequence
aBbAaB . . . The polar 0001.surfaces should be unstable because of the normal dipole moment. However, a long-range
1=1.order is obtained after several Arq-8008C cycles. We investigated, by grazing incidence X-ray diffraction XRD.,
both the O- and Zn-terminated faces, issued from a single substrate. In both cases, the coherent domain width was found
between 180 and 100 A° . This is the average size of the terraces, limited by bilayer steps, and thus either a or b terminated.
Several intensity rods along the surface normal.were analysed, attesting that the surface is close to bulk truncation no
stacking fault.. The effects of relaxation or non-stoichiometry are strongly damped by the contribution of the two types of
terraces. In the Zn case, the atomic displacements are not significant outward relaxation of q0.05 A°., whereas in the O
case, four layers have to be displaced inward relaxation by y0.3 A°.. The fits are greatly improved allowing for partial
occupancy in the topmost planes: 0.75 for the external plane in the Zn case, a result which fits well with the electrostatic
arguments for the cancellation of the dipole moment, and 1.3, 0.7, for the two topmost planes on the O surface. Impurity or
Zn atoms substituting the O atoms could explain these latter values. q2000 Elsevier Science B.V. All rights reserved
