Effect of Spin−Orbit Coupling on Reduction Potentials of Octahedral Ruthenium(II/III) and Osmium(II/III) Complexes

Effect of Spin−Orbit Coupling on Reduction Potentials of Octahedral Ruthenium(II/III) and Osmium(II/III) Complexes

Reduction potentials of several M2+/3+ (M = Ru, Os) octahedral complexes, namely, [M(H2O)6]2+/3+, [MCl6]4−/3−, [M(NH3)6]2+/3+, [M(en)3]2+/3+ [M(bipy)3]2+/3+, and [M(CN)6]4−/3−, were calculated using the CASSCF/CASPT2/CASSI and MRCI methods including spin−orbit coupling (SOC) by means of first-order...

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Published in:Journal of the American Chemical Society Vol. 130; no. 33; pp. 10947 - 10954
Main Authors: Srnec, Martin, Chalupský, Jakub, Fojta, Miroslav, Zendlová, Lucie, Havran, Luděk, Hocek, Michal, Kývala, Mojmír, Rulíšek, Lubomír
Format: Journal Article
Language:English
Published: United States American Chemical Society 20-08-2008
Subjects:
Computer Simulation
Models, Chemical
Models, Molecular
Molecular Structure
Organometallic Compounds - chemistry
Osmium - chemistry
Oxidation-Reduction
Quantum Theory
Ruthenium - chemistry
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Summary:Reduction potentials of several M2+/3+ (M = Ru, Os) octahedral complexes, namely, [M(H2O)6]2+/3+, [MCl6]4−/3−, [M(NH3)6]2+/3+, [M(en)3]2+/3+ [M(bipy)3]2+/3+, and [M(CN)6]4−/3−, were calculated using the CASSCF/CASPT2/CASSI and MRCI methods including spin−orbit coupling (SOC) by means of first-order quasi-degenerate perturbation theory. It was shown that the effect of SOC accounts for a systematic shift of approximately −70 mV in the reduction potentials of the studied ruthenium (II/III) complexes and an approximately −300 mV shift for the osmium(II/III) complexes. SOC splits the sixfold-degenerate 2T2g ground electronic state (in ideal octahedral symmetry) of the M3+ ions into the E(5/2)g Kramers doublet and G(3/2)g quartet, which were calculated to split by 1354−1573 cm−1 in the Ru3+ complexes and 4155−5061 cm−1 in the Os3+ complexes. It was demonstrated that this splitting represents the main contribution to the stabilization of the M3+ ground state with respect to the closed-shell 1A1g ground state in M2+ systems. Moreover, it was shown that the accuracy of the calculated reduction potentials depends on the calculated solvation energies of both the oxidized and reduced forms. For smaller ligands, it involves explicit inclusion of the second solvation sphere into the calculations, whereas implicit solvation models yield results of sufficient accuracy for complexes with larger ligands. In such cases (e.g., [M(bipy)3]2+/3+ and its derivatives), very good agreement between the calculated (SOC-corrected) values of the reduction potentials and the available experimental values was obtained. These results led us to the conclusion that especially for Os2+/3+ complexes, inclusion of SOC is necessary to avoid systematic errors of ∼300 mV in the calculated reduction potentials.
Bibliography:istex:0851BD95BAE479FA37650FACDC47C7551AE50592
Equilibrium geometries and molecular energies of all the studied molecules (for all of the methods used) and tables describing the basis-set dependence of the calculated CASSCF(5,3)/CASPT2/CASSI energy splittings and the convergence of MRCI values with the number of excited states. This material is available free of charge via the Internet at http://pubs.acs.org.
ark:/67375/TPS-Q1KSLNCX-C
ObjectType-Article-1
SourceType-Scholarly Journals-1
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content type line 23
ISSN:0002-7863
1520-5126
DOI:10.1021/ja800616s