Photophysical and structural properties of cyanoruthenate complexes of hexaazatriphenylene

The tritopic bridging ligand hexaazatriphenylene (HAT) has been used to prepare the mono-, di-, and trinuclear cyanoruthenate complexes [Ru(CN) ₄(HAT)]^2- ([1]^2-), [{Ru(CN)₄} ₂(μ₂-HAT)]^4- ([2]^4-), and [{Ru(CN)₄}₃(μ₃-HAT)]^6- ([3] ^6-). These complexes are of interest both for their photophysical properties and ability to act as sensitizers, associated with strong MLCT absorptions; and their structural properties, with up to 12 externally directed cyanide ligands at a single "node" for preparation of coordination networks. The complexes are strongly solvatochromic, with broad and intense MLCT absorption manifolds arising from the presence of low-lying π* orbitals on the HAT ligand, as confirmed by DFT calculations; in aprotic solvents [3]^6- is a panchromatic absorber of visible light. Although nonluminescent in fluid solution, the lowest MLCT excited states have lifetimes in D₂O of tens of nanoseconds and could be detected by time-resolved IR spectrosocopy. For dinuclear [2]^4- and trinuclear [3]^6- the TRIR spectra are indicative of asymmetric MLCT excited states containing distinct Ru(III) and Ru(II) centers on the IR time scale. The complexes show red ³MLCT luminescence as solids and in EtOH/MeOH glass at 77 K. Ln(III) salts of [1]^2-, [2]^4-, and [3]^6- form infinite coordination networks based on Ru-CN-Ln bridges with a range of one-, two-, and three-dimensional polymeric structures. In the Yb(III) and Nd(III) salts of [3]^6- the complex anion forms an 8-connected node. Whereas all of the Gd(III) salts show strong ³MLCT luminescence in the solid state, the Ru-based emission in the Nd(III) and Yb(III) analogues is substantially quenched by Ru → Ln photoinduced energy transfer, which results in sensitized near-infrared luminescence from Yb(III) and Nd(III).