Density Functional Theory Analysis of Anthraquinone Derivative Hydrogenation over Palladium Catalyst

A density functional theory (DFT) analysis was conducted on the hydrogenation of 2‐alkyl‐anthraquinone (AQ), including 2‐ethyl‐9,10‐anthraquinone (eAQ) and 2‐ethyl‐5,6,7,8‐tetrahydro‐9,10‐anthraquinone (H 4 eAQ), to the corresponding anthrahydroquinone (AQH 2 ) over a Pd 6 H 2 cluster. Hydrogenation of H 4 eAQ is suggested to be more favorable than that of eAQ owing to a higher adsorption energy of the reactant (H 4 eAQ), lower barrier of activation energy, and smaller desorption energy of the target product (2‐ethyl‐5,6,7,8‐tetrahydro‐9,10‐anthrahydroquinone, H 4 eAQH 2 ). For the most probable reaction routes, the energy barrier of the second hydrogenation step of AQ is circa 8 kcal mol −1 higher than that of the first step. Electron transfer of these processes were systematically investigated. Facile electron transfer from Pd 6 H 2 cluster to AQ/AQH intermediate favors the hydrogenation of C=O. The electron delocalization over the boundary aromatic ring of AQ/AQH intermediate and the electron‐withdrawing effect of C=O are responsible for the electron transfer. In addition, a pathway of the electron transfer is proposed for the adsorption and subsequent hydrogenation of AQ on the surface of Pd 6 H 2 cluster. The electron transfers from the abstracted H atom (reactive H) to a neighbor Pd atom (Pd H ), and finally goes to the carbonyl group through the C 4 atom of AQ aromatic ring (C 4 ).