Adsorption and dissociation of O2 at Be(0001): First-principles prediction of an energy barrier on the adiabatic potential energy surface

Abstract

The adsorption and dissociation of O2 molecules at the Be(0001) surface is studied by using density-functional theory within the generalized gradient approximation and a supercell approach. The physi- and chemisorbed molecular precursor states are identified to be along the parallel and vertical channels, respectively. It is shown that the HH-Z (see the text for definition) channel is the most stable channel for the molecular chemisorption of O2. The electronic and magnetic properties of this most stable chemisorbed molecular state are studied, which shows that the electrons transfer forth and back between the spin-resolved antibonding π molecular orbitals and the surface Be sp states. A distinct covalent weight in the molecule-metal bond is also shown. The dissociation of O2 is determined by calculating the adiabatic potential energy surfaces, wherein the T-Y channel is found to be the most stable and favorable for the dissociative adsorption of O2. Remarkably, we predict that unlike the other simple sp metal surfaces such as Al(111) and Mg(0001), the adiabatic dissociation process of O2 at Be(0001) is an activated type with a sizeable energy barrier.