The tripyrrin-1,14-dione scaffold of urinary pigment uroerythrin coordinates divalent palladium as a planar tridentate ligand. Spectroscopic, structural and computational investigations reveal that the tripyrrindione ligand binds as a dianionic radical, and the resulting complex is stable at room temperature. One-electron oxidation and reduction reactions do not alter the planar coordination sphere of palladium(II) and lead to the isolation of two additional complexes presenting different redox states of the ligand framework. Unaffected by stability problems common to tripyrrolic fragments, the tripyrrindione ligand offers a robust platform for ligand-based redox chemistry.
The ability of tetrapyrrolic macrocycles to stabilize unpaired electrons and engage in π–π interactions is essential for many electron-transfer processes in biology and materials engineering. Herein, we demonstrate that the formation of π dimers is recapitulated in complexes of a linear tripyrrolic analog of naturally occurring pigments derived from heme decomposition. Hexaethyltripyrrindione (H3TD1) coordinates divalent transition metals (i.e., Pd, Cu, Ni) as a stable dianionic radical and was recently described as a robust redox-active ligand. The resulting planar complexes, which feature a delocalized ligand-based electronic spin, are stable at room temperature in air and support ligand-based one-electron processes. We detail the dimerization of neutral tripyrrindione complexes in solution through electron paramagnetic resonance (EPR) and visible absorption spectroscopic methods. Variable-temperature measurements using both EPR and absorption techniques allowed determination of the thermodynamic parameters of π dimerization, which resemble those previously reported for porphyrin radical cations. The inferred electronic structure, featuring coupling of ligand-based electronic spins in the π dimers, is supported by density functional theory (DFT) calculations.
The
ability of bilins and other biopyrrins to form fluorescent zinc complexes
has been known for more than a century; however, the exact identity
of the emissive species remains uncertain in many cases. Herein, we
characterize the hitherto elusive zinc complex of tripyrrin-1,14-dione,
an analogue of several orange urinary pigments. As previously observed
for its Pd(II), Cu(II), and Ni(II) complexes, tripyrrindione binds
Zn(II) as a dianionic radical and forms a paramagnetic complex carrying
an unpaired electron on the ligand π-system. This species is
stable at room temperature and undergoes quasi-reversible ligand-based
redox chemistry. Although the complex is isolated as a coordination
dimer in the solid state, optical absorption and electron paramagnetic
resonance spectroscopic studies indicate that the monomer is prevalent
in a tetrahydrofuran solution. The paramagnetic Zn(II) tripyrrindione
complex is brightly fluorescent (λabs = 599 nm, λem = 644 nm, ΦF = 0.23 in THF), and its study
provides a molecular basis for the observation, made over several
decades since the 1930s, of fluorescent behavior of tripyrrindione
pigments in the presence of zinc salts. The zinc-bound tripyrrindione
radical is thus a new addition to the limited number of stable radicals
that are fluorescent at room temperature.
The dipyrrin-1,9-dione scaffold of heme metabolite propendyopent coordinates late transition metals (Co, Ni, Cu, and Zn) forming homoleptic, pseudo-tetrahedral complexes. Electrochemical and spectroscopic studies reveal that the monoanionic, bidentate ligands behave as electron reservoirs as the complexes reversibly host one or two ligand-based radicals.
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