The electronic structure and bonding of H pairs at Σ=5 BCC Fe grain boundary

The H–Fe interaction at a grain boundary (GB) in BCC Fe was studied using qualitative electronic structure calculations in the framework of the atom superposition and electron delocalization molecular orbital (ASED-MO) theory. Calculations were performed using an Fe196 cluster to simulate the 36.9° [1 0 0] {0 1 3} symmetrical tilt GB structure. The most stable positions for one H atom and two H atoms at the GB core were determined. The total energy of the cluster decreases when the H atoms are at that location, making it a possible site for H accumulation. An analysis of the orbital interaction reveals that H–Fe bonding involves mainly the Fe 4s and H 1s orbitals. In general, H drain charge from the first neighbor Fe atoms. The crystal orbital overlap population (COOP) curves gives a measure of Fe–Fe bond weakening due to H segregate at GB. Some Fe–Fe bonds in the GB plane shows a 60% decrease in the overlap population when H is present. H–H interaction was also analyzed. Although some H–H association is reveled no bond is formed between the impurity atoms.