DETERMINATION OF TiO2(110) SURFACE RELAXATION BY VARIABLE POLARIZATION PHOTOELECTRON DIFFRACTION

Abstract

A new method to determine the surface relaxation by means 0 of photoelectron diffraction (PED) from an s-core level has been applied to the (1 × 1)- TiO 2(110) surface. Complete 2π solid angle PED patterns for both oxygen 1s and titanium 3s core level peak intensities have been measured at the ALOISA beamline (Elettra Synchrotron, Italy) in two different photon polarization/electron detection geometrical configurations: one with the photon polarization vector parallel to the surface normal (TM polarization) and the other with the photon polarization vector perpendicular to the surface normal (TE polarization). In the latter case the PED sensitivity to the vertical spacing is enhanced. Because forward scattering is suppressed on the node of the primary wave along the surface normal, the relative weight of the distance-sensitive higher order interference fringes is enhanced. The opposite occurs for the TM polarization, which enhances the PED sensitivity to lateral spacing at grazing emission angles. The experimental PED patterns are compared with the theoretical simulations calculated for the relaxed and unrelaxed TiO 2(110) surface. The results prove the feasibility of the method and the adequacy of the PED technique to the studies of relaxation phenomena at crystal surfaces.