DFT-GGA errors in NO chemisorption energies on (111) transition metal surfaces: Possible origins and correction schemes

Abstract

Here we investigate whether well-known DFT-GGA errors in predicting the chemisorption energy (E chem) of CO on transition metal surfaces manifest in analogous NO chemisorption systems. To verify the occurrence of DFT-GGA overestimation of the back-donation mechanism in NO Chemisorption, we use electronic structure analysis to show that the partially filled molecular NO 2π* orbital rehybridizes with the transition metal d-band to form new bonding and anti-bonding states. We relate the back-donation charge transfer associated with chemisorption to the promotion of an electron from the 5σ orbital to the 2π* orbital in the gas-phase NO G2-← X2 excitation. We establish linear relationships between E chem and E G← X and go on to formulate an E chem correction scheme in the style of Mason et al., [Physical Review B 69, 161401(R)]. We apply the NO E chem correction method to the (111) surfaces of Pt, Pd, Rh, and Ir, with NO chemisorption modeled at a coverage of 0.25 ML. We note that both the slope of E chem vs. E G← X and the dipole moment depend strongly on adsorption site for each metal, and we use this fact to construct an approximate correction scheme which we go on to test using NO/Pt(100) chemisorption.