Structural and energetic properties of cluster models of anatase-supported single late transition metal atoms: a density functional theory benchmark study.

Context: Single-atom catalytic systems constitute an intriguing research topic due to their inherently different chemical behavior as compared to classic heterogeneous catalysts. In this study, cluster systems representing single late transition metal atoms adsorbed on anatase were constructed starting from previously generated periodic models and subjected to a density functional theory (DFT) benchmark study. The ability of different density functional approximations representing all rungs of the Jacob's Ladder classification to accurately describe bond lengths and adsorption energies was assessed for these clusters with the aim of revealing the functional that allows to retain the structural characteristics of the initial periodic system, while also delivering reliable energetics.

Investigation of iron release from the N- and C-lobes of human serum transferrin by quantum chemical calculations.

Human serum transferrin binds ferric ions with high affinity and delivers them into cells receptor-mediated endocytosis upon a decrease in pH in the endosome. Protonation events and conformational changes are known to play an important role in iron-release though the release is not yet fully understood. Human serum transferrin consists of two similar lobes which release iron at different rates.