Abstract:
A detailed first-principles density functional analysis of the geometric and electronic properties of ethylene adsorbed on the dimer reconstructed Si(001)-(2 x 1) surface is presented. This theoretical study was carried out in close reference to a recent angle-resolved photoemission spectroscopy investigation of the same adsorption system. Adsorbate weighted Kohn-Sham one-particle spectra are calculated and compared to the band structure derived from the angle-resolved photoemission spectra. In addition, the symmetry character of the concomitant Bloch waves is determined to yield information which can directly be related to the results of a dipole selection rule analysis of the corresponding photoemission signals. Total energy minimization of a model slab reveals a distortion of the adsorption complex at saturation coverage to local C-2 symmetry involving an 11 degrees rotation of the ethylene molecule around the surface normal and a 27 degrees twist of the methylene groups around the C-C axis. This finding is confirmed by a comparison of the calculated band dispersions with those found in the angle-resolved ultraviolet photoelectron spectroscopy (ARUPS) experiments. The driving forces for the distortion of the adsorption complex can be traced to direct Pauli repulsion between the hydrogen atoms of neighboring ethylene molecules and to a bonding overlap contribution from the ethylene 1b(2g)-derived orbitals of the adlayer.