A new uranyl triphosphonate constructed from semi-rigid triphosphonate ligand: New method for the construction of higher dimensional uranyl phosponates

Fabrication of New Uranyl Phosphonates by Varying Quaternary Ammonium Cation: Synthesis, Structure, Luminescent Properties, and Single-Crystal to Single-Crystal Transformation

Four new uranyl triphosphonates, namely, [N(CH₄)₄][UO₂(H₃L)][H₂O] (1), [(UO₂)_1.5(H₃L)(H₂O)_1.5][H₂O] (2), [NBu₄][(UO₂)_3.5(H₂L)₂][(H₂O)_4.5] (3), and [(UO₂)_1.5(H₃L)(H₂O)_2.5][(H₂O)_2.5] (4), where H₆L = benzene-1,3,5-triyltris(methylene)triphosphonic acid, were obtained from a triphosphonate ligand in the presence of different quaternary ammonium cations. The structural characterization revealed that the introduction of quaternary ammonium cation had a major impact on the structure formation of uranyl phosphonates. Compound 1 possesses a three-dimensional anionic framework structure. Tetramethylammonium cations are accommodated in the channels, serving as counterions and structure directing agents. Compound 2 also displays a three-dimensional framework structure but is neutral, because the tetrapropylammonium cations are not involved in the crystal structure. Compound 3 has an intercalation structure; between the layers are the tetrabutylammonium cations, balancing the charge and strengthening the supramolecular structure with C-H···O interactions. No obvious uptake of N₂ and CO₂ could be observed for compound 2 due to the shrinkage of the framework and structural transformation. Compound 2 undergoes single-crystal to single-crystal transformation under vacuum, leading to the formation of compound 4, which possesses a two-dimensional layer structure. The photophysical properties of these compounds were also investigated.