文摘
Synthesis and X-ray diffraction structures of cis and trans isomers of ruthenium and osmium metal complexes of general formulas (nBu4N)[cis-MCl4(NO)(Hind)], where M = Ru (1) and Os (3), and (nBu4N)[trans-MCl4(NO)(Hind)], where M = Ru (2) and Os (4) and Hind = 1H-indazole are reported. Interconversion between cis and trans isomers at high temperatures (80鈥?30 掳C) has been observed and studied by NMR spectroscopy. Kinetic data indicate that isomerizations correspond to reversible first order reactions. The rates of isomerization reactions even at 110 掳C are very low with rate constants of 10鈥? s鈥? and 10鈥? s鈥? for ruthenium and osmium complexes, respectively, and the estimated rate constants of isomerization at room temperature are of ca. 10鈥?0 s鈥?. The activation parameters, which have been obtained from fitting the reaction rates at different temperatures to the Eyring equation for ruthenium [螖Hcis-trans鈥?/sup>= 122.8 卤 1.3; 螖Htrans-cis鈥?/sup>= 138.8 卤 1.0 kJ/mol; 螖Scis-trans鈥?/sup>= 鈭?8.7 卤 3.6; 螖Strans-cis鈥?/sup>= 31.8 卤 2.7 J/(mol路K)] and osmium [螖Hcis-trans鈥?/sup>= 200.7 卤 0.7; 螖Htrans-cis鈥?/sup>= 168.2 卤 0.6 kJ/mol; 螖Scis-trans鈥?/sup>= 142.7 卤 8.9; 螖Strans-cis鈥?/sup>= 85.9 卤 3.9 J/(mol路K)] reflect the inertness of these systems. The entropy of activation for the osmium complexes is highly positive and suggests the dissociative mechanism of isomerization. In the case of ruthenium, the activation entropy for the cis to trans isomerization is negative [鈭?8.6 J/(mol路K)], while being positive [31.0 J/(mol路K)] for the trans to cis conversion. The thermodynamic parameters for cis to trans isomerization of [RuCl4(NO)(Hind)]鈭?/sup>, viz. 螖H掳 = 13.5 卤 1.5 kJ/mol and 螖S掳 = 鈭?.2 卤 3.4 J/(mol路K) indicate the low difference between the energies of cis and trans isomers. The theoretical calculation has been carried out on isomerization of ruthenium complexes with DFT methods. The dissociative, associative, and intramolecular twist isomerization mechanisms have been considered. The value for the activation energy found for the dissociative mechanism is in good agreement with experimental activation enthalpy. Electrochemical investigation provides further evidence for higher reactivity of ruthenium complexes compared to that of osmium counterparts and shows that intramolecular electron transfer reactions do not affect the isomerization process. A dissociative mechanism of cis鈫?i>trans isomerization has been proposed for both ruthenium and osmium complexes.
