Stable Platinum(IV) Corroles: Synthesis, Molecular Structure, and Room-Temperature Near-IR Phosphorescence

A series of stable Pt(IV) corrole complexes with the general formula Pt-IV[TpXPC](m/p-C6H4CN)(py), where TpXPC(3-) is the trianion of a tris(p-X-phenyl)corrole and X = CF3, H, and CH3, has been synthesized, affording key physicochemical data on a rare and elusive class of metallocorroles. Single-crystal X-ray structures of two of the complexes revealed very short equatorial Pt-N distances of 1.94-1.97 angstrom, an axial Pt-C distance of similar to 2.03 angstrom, and an axial Pt-N distance of similar to 2.22 angstrom. The complexes exhibit Soret maxima at similar to 430 nm, which are essentially independent of the meso-aryl Para substituents, and strong Q bands with the most intense peak at 595-599 nm. The substituent-independent Soret maxima are consistent with an innocent Pt-IV-corrole(3-) description for the complexes. The low reduction potentials (-1.45 +/- 0.08 V vs saturated caloinel reference electrode) also support a highly stable Pt(IV) ground state as opposed to a noninnocent corrole(center dot 2-) description. The reductions, however, are irreversible, which suggests that they involve concomitant cleavage of the Pt-aryl bond. Unlike Pt(IV) porphyrins, two of the complexes, Pt-IV[TpXPC](m-C6H4CN)(py) (X = CF3 and CH3), were found to exhibit room-temperature near-IR phosphorescence with emission maxima at 813 and 826 nm, respectively. The quantum yield of similar to 0.3% is comparable to those observed for six-coordinate Ir(III) corroles.