Abstract
We performed density functional theory calculations using the full-potential linearized augmented plane wave method and generalized gradient approximation to investigate the interaction of hydrogen with Fe surface layers in the Fe/M(0
0
1) system, where M=Cu, Ag. The adsorption of hydrogen is found to be preferable at bridge sites in both H/Fe(0
0
1) and H/Fe/Ag(0
0
1), whereas the preferred sites are the fourfold site above the surface layer in the H/Fe/Cu(0
0
1) system. The adsorption energies are enhanced due to Cu and Ag substrates as compared to Fe(0
0
1) substrates. The local density of states at the Fermi level and the magnetic moments are reduced due to the presence of H for the different systems.
►The adsorption of H on transition metal surfaces is of a great interest in catalysis and metallurgy. ►Copper and silver substrates enhance the adsorption energy as compared to that of the H/Fe(0
0
1). ►Reduction of the magnetism for surface layers occurs due to the hybridization of H s band and Fe d bands.