Theoretical Investigations of Uranyl−Ligand Bonding: Four- and Five-Coordinate Uranyl Cyanide, Isocyanide, Carbonyl, and Hydroxide Complexes

Abstract

The coordination and bonding of equatorial hydroxide, carbonyl, cyanide (CN^-), and isocyanide (NC^-) ligands with uranyl dication, [UO₂]²⁺, has been studied using density functional theory with relativistic effective core potentials. Good agreement is seen between experimental and calculated geometries of [UO₂(OH)₄]^2-. Newly predicted ground-state structures of [UO₂(OH)₅]^3-, [UO₂(CO)₄]²⁺, [UO₂(CO)₅]²⁺, [UO₂(CN)₄]^2-, [UO₂(CN)₅]^3-, [UO₂(NC)₄]^2-, and [UO₂(NC)₅]^3- are reported. Four-coordinate uranyl isocyanide complexes are the predicted gas-phase species while five-coordinate uranyl cyanide complexes are energetically favorable in aqueous solution. Small energy differences between cyanide and isocyanide complexes indicate the energetic feasibility of mixed cyanide and isocyanide complexes. A D_2d uranyl tetrahydroxide is the dominant gas-phase and aqueous species, but formation of uranyl carbonyl complexes is seen to be exothermic in the gas-phase and endothermic in aqueous solution.