Extended Structures and Physicochemical Properties of Uranyl-Organic Compounds

The ability of uranium to undergo nuclear fission has been exploited primarily to manufacture nuclear weapons and to generate nuclear power. Outside of its nuclear physics, uranium also exhibits rich chemistry, and it forms various compounds with other elements. Among the uranium-bearing compounds, those with a uranium oxidation state of +6 are most common and a particular structural unit, uranyl UO22+ is usually involved in these hexavalent uranium compounds. Apart from forming solids with inorganic ions, the uranyl unit also bonds to organic molecules to generate uranyl organic coordination materials. If appropriate reaction conditions are employed, uranyl organic extended structures (1-D chains, 2-D layers, and 3-D frameworks) can be obtained. Research on uranyl organic compounds with extended structures allows for the exploration of their rich structural chemistry, and such studies also point to potential applications such as in materials that could facilitate nuclear waste disposal. In this Account, we describe the structural features of uranyl organic compounds and efforts to synthesize uranyl organic compounds with desired structures. We address strategies to construct 3-D uranyl organic frameworks through rational selection of organic ligands and the incorporation of heteroatoms. The UO22+ species with inactive U=0 double bonds usually form bipyramidal polyhedral structures with ligands coordinated at the equatorial positions, and these polyhedra act as primary building units (PBUs) for the construction of uranyl organic compounds. The geometry of the uranyl ions and the steric arrangements and functionalities of organic ligands can be exploited in the the design of uranyl organic extended structures, We also focus on the investigation of the promising physicochemical properties of uranyl organic compounds. Uranyl organic materials with an extended structure may exhibit attractive properties, such as photoluminescence, photocatalysis, photocurrent, and photovoltaic responses. In particular, the intriguing, visible-light photocatalytic activities of uranyl organic compounds are potentially applicable in decomposition of organic pollutants and in water-splitting with the irradiation of solar light. We ascribe the photochemical properties of uranyl-organic compounds to the electronic transitions within the U=0 bonds, which may be affected by the presence of organic ligands.