The influence of trans-ligand to NO on the thermal stability of photoinduced side-bond coordinated linkage isomer

The influence of trans-to NO ligand (X) on the thermal stability of transient side-on coordinated nitrosyl linkage isomer (MS2) is investigated in a series of trans-[RuNOPy4X](PF6)2 (X = F- (RuF),...

Tuning the structure and photoinduced linkage isomerism of tetrapyridine nitrosyl ruthenium(ii) complexes by changing the trans-to-NO coordinated ligand

Ruthenium nitrosyl complexes were prepared with various trans-to-NO ligands. These compounds form Ru–ON metastable states upon blue-light excitation and the corresponding thermal stabilities were determined.

Calixsmaragdyrin: A Versatile Ligand for Coordination Complexes

The Ru(II) and BF₂ complexes of calixsmaragdyrin were prepared under simple reaction conditions and characterized by HR-MS, 1D and 2D NMR spectroscopy, optical spectroscopy, and electrochemistry, and the structure of the Ru(II) complex of calixsmaragdyrin was elucidated by X-ray crystallography. The crystal structure of the Ru(II) complex revealed that the Ru(II) ion is hexacoordinate with the three pyrrole nitrogen ligands from the tripyrrin unit of the calixsmaragdyrin macrocycle, and the remaining coordination sites of Ru(II) ion were occupied by two carbonyl groups and one hydroxyl (-OH) group. The calixsmaragdyrin macrocycle in the Ru(II) complex was distorted with a dome-like structure. In the BF₂ complex of calixsmaragdyrin, the BF₂ unit was bound to two pyrrolic nitrogens of the dipyrrin moiety of calixsmaragdyrin as deduced by detailed 1- and 2-dimensional NMR spectroscopy studies. The Ru(II) complex displayed a strong Soret-like absorption band at 449 nm with the absence of Q-bands, whereas the BF₂ complex showed a Soret-like band at 475 nm with two well-defined Q-bands at 787 and 883 nm, respectively. Quantum mechanical DFT calculations yielded relaxed equilibrium structures that were similar to the X-ray crystal structures, and the related charge density distributions indicated that the d orbital of the Ru(II) ion was contributing to the HOMO and LUMO states. In addition, TD-DFT calculations successfully reproduced the large bathochromic shifts, oscillator strengths, and electronic transitions that were observed in the experimental absorption spectra of all three complexes. Both the Ru(II) and the BF₂ complexes of calixsmaragdyrin were stable under redox conditions.