(513ev) Tuning Surface Characteristics of Graphene Aerogel to Control Catalytic Properties of Atomically Dispersed Iridium Complexes

The influence of annealing conditions on the surface characteristics of graphene-based materials for their tunability on the electronic structure of the atomically dispersed supported iridium complexes anchored on these reduced GA supports and on partial hydrogenation of 1-3 butadiene reaction was investigated.

Reduced GA-supported Ir(CO)₂ complexes were synthesized by the reaction of Ir(CO)₂(acac) with GA samples at an Ir loading of 10 wt.%. Detailed characterization was done to understand ligand-support interactions as well as catalytic activity.

To probe the consequences of these changes on the electronic environment of atomically dispersed supported metal complexes, Ir(CO)₂ complexes were anchored on these supports, and investigated the variation of the partial hydrogenation selectivity with the corresponding ν(CO) band positions of carbonyl ligands on the iridium complexes. Data presented a decreasing trend between partial selectivity of 1-3 butadiene hydrogenation and ν(CO) band positions (image), indicating that more electron rich iridium sites became more selective as the annealing temperature decreases. This comparison illustrated a strong correlation between the partial hydrogenation activity of the supported complexes with the corresponding ν(CO) band positions probing the electron density on iridium. Results present a broad potential for tuning the catalytic properties of atomically dispersed supported metal complexes. GA but also provides opportunities for tuning the selectivity of partial hydrogenation reaction in a wide range.