Electronic structure alternatives in nitrosylruthenium complexes. Dalton Transactions, (39)19:4471--4478, 2010. [PUMA: active complex electronic ligand nitrosyl redox review ruthenium structure]
Spectroelectrochemistry and DFT Analysis of a New RuNOn Redox System with Multifrequency EPR Suggesting Conformational Isomerism in the RuNO7 State. Inorganic Chemistry, (46)22:9254--9261, 2007. [PUMA: DFT EPR bipyrimidine complex electrochem isomerism multifrequency nitro nitrosyl prepn redn;conformational redox ruthenium system system;spectroelectrochem terpyridine]
Redox Properties of Ruthenium Nitrosyl Porphyrin Complexes with Different Axial Ligation: Structural, Spectroelectrochemical (IR, UV-Visible, and EPR), and Theoretical Studies. Inorganic Chemistry, (47)16:7106--7113, 2008. [PUMA: axial complex effect effect;spectroelectrochem electrochem ligand ligation nitrosyl porphyrin reaction redox ruthenium study tetraphenylporphyrin]
Complex Series Ru(tpy)(dpk)(X)n+ (tpy = 2,2': 6',2''-Terpyridine; dpk = 2,2'-Dipyridyl Ketone; X = Cl-, CH3CN, NO2-, NO+, NO.bul., NO-): Substitution and Electron Transfer, Structure, and Spectroscopy. Inorganic Chemistry, (44)17:6092--6099, 2005. [PUMA: anion cation complex complex;nitrosyl dipyridyl electrochem ketone ligand nitroso nitrosyl oxidn precursor;kinetics prepn radical reactivity redox ruthenium terpyridine]
Spectroelectrochemical Evidence for the Nitrosyl Redox Siblings NO+, NO., and NO- Coordinated to a Strongly Electron-Accepting FeII Porphyrin: DFT Calculations Suggest the Presence of High-Spin States after Reduction of the FeII-NO- Complex. Chemistry - A European Journal, (17)28:7868-7874, S7868/1-S7868/9, 2011. [PUMA: DFT accepting complex;spectroelectrochem electron iron nitrogen nitrosyl oxide porphyrin redn redox sibling spin state]