Ab initio molecular orbital study of the electronic structure and the rotational barrier of benzene in the helicopter complex Os3(CO)9(C6H6)

Riehl, Jean Frederic; Koga, Nobuaki; Morokuma, Keiji

doi:10.1021/om00036a019

Cited by 21 publications

(15 citation statements)

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“…Some of us have previously investigated the interaction of benzene with the (CpCo) 3 cluster, using the approximate Fenske−Hall SCF method . Our results have later been confirmed by several extended Hückel, Fenske−Hall, and ab initio studies on the valence isoelectronic derivatives [{(CO) 3 M} 3 (μ 3 -C 6 H 6 )] (M = Ru, Os) . There is an electronic preference for a staggered conformation of the benzene relative to the metal triangle and for an alternation of stronger (shorter) and weaker (longer) bonds in the ring, the shorter bonds eclipsing the metal atoms.…”

Section: Discussionsupporting

confidence: 61%

Organometallic Cluster Complexes with Face-Capping Arene Ligands. 8. Nucleophilic Reactivity of Cluster Complexes with Face-Capping Arene Ligands: Metal vs Ligand Protonation

et al. 1996

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Protonation of some cluster complexes with face-capping arene ligands has been studied. The complexes [(CpCo) 3 (µ 3 -η 2 :η 2 :η 2 -arene)] [arene ) isopropylbenzene (1a), 1,4-diethylbenzene (1b), 1,2-diphenylethane (1c), 1,1-diphenylethane (1d)] are protonated at the metal clusters to afford the hydrido cluster cations [(µ 3 -H)(CpCo) 3 (µ 3 -η 2 :η 2 :η 2 -arene)] + (3a-d). The crystal structure of 3d[CF 3 COO] -‚H 2 O has been determined. In marked contrast, derivatives with µ 3 -arenes bearing unsaturated substituents [arene ) R-methylstyrene (2a), β-methylstyrene (2b), p-methoxystyrene (2c)] take up a proton at the β-carbon atom of the side chain to give the novel metal cluster stabilized benzyl cations [(CpCo -c). On attempted crystallization as a tetrafluoroborate, the derivative 4a with a protonated R-methylstyrene ligand is converted to the paramagnetic [(CpCo) 3 {µ 3 -η 2 :η 2 :η 2 -(R-methylstyrene)}] + (2a + ), the crystal structure of which is reported. The different sites of protonation for 1 and 2 are explained by an extended Hu ¨ckel (EH) MO study, using both charge and overlap control arguments. The paramagnetic cation was studied, and its geometry found to agree very well with the experimentally determined structure described for 2a + , suggesting that it is indeed this the species being observed. A detailed analysis of the geometrical preferences of the protonation products 4 was carried out, using EH and density functional methods. A slipped eclipsed arrangement of a nonplanar η 7 -benzyl ligand on top of the Co 3 cluster with the side chain bent away appears to be energetically favored over a staggered substituted benzene.

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Section: Discussionsupporting

confidence: 61%

Organometallic Cluster Complexes with Face-Capping Arene Ligands. 8. Nucleophilic Reactivity of Cluster Complexes with Face-Capping Arene Ligands: Metal vs Ligand Protonation

et al. 1996

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“…Morokuma and co-workers studied the bonding in Os 3 -(CO) 9 (C 6 H 6 ) using single-point MP2 energy calculations on HF-optimized structures, and EH for orbital analysis. [5] Some of us qualitatively analyzed the bonding of orthometallated α-diimines to HOs 3 (CO) 9 . [6a] In this work, DFT calculations [7] performed under different conditions and on models of three Os 3 (CO) 10 (α-diimine) clusters are described, and the reliability of extended Hückel [8] calculations on these systems is discussed.…”

Section: Introductionmentioning

confidence: 99%

Theoretical Studies of [Os3(CO)10(α-Diimine)]: Structures, Frontier Orbitals and Bonding

Calhorda¹,

Hunstock²,

Veiros³

et al. 2001

Eur. J. Inorg. Chem.

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DFT calculations were performed on Os 3 (CO) 10 (α-diimine) clusters, for α-diimine = DAB (1,4-diaza-1,3-butadiene), PYCA (σ-N,σ-NЈ-pyridine-2-carbaldehyde-imine), and BIPY (2,2Ј-bipyridine). Geometry optimizations were performed for several models of the possible isomers under different conditions. Axial isomers were always found to be the most stable, in agreement with the available X-ray determined structures. A full optimization of the geometry was required in order to improve the quality of the results, but the dis-

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“…This is also the case for 1 after exhaustive electrolysis for which we observe a uniform sharpening of the 1 H NMR resonances for the small amount of unreduced cluster as the temperature is decreased Density functional theory calculations and spectral simulations: The density functional theory (DFT) approach has proven to be a very useful method for understanding chemical bonding in transition-metal and polymetallic complexes. [17,18] DFT methods have been previously successfully applied to calculations of triosmium clusters: Morokuma and co-workers studied the bonding in [Os 3 (CO) 9 (C 6 H 6 )], [19] and Calhorda et al studied in detail structures, frontier orbitals, and bonding of [Os 3 (CO) 10 (a-diimine)] clusters. [20] The most important features of the molecular-orbital description of 1 are the characteristics of the HOMO and LUMO orbitals.…”

mentioning

confidence: 99%

Spectroscopic and Computational Investigations of Stable Radical Anions of Triosmium Benzoheterocycle Clusters

Nervi

Gobetto

Milone

et al. 2003

Chemistry A European J

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The variable temperature (1)H and (13)C NMR and EPR spectra of the stable radical anions [Os(3)(CO)(9)(micro(3)-eta(2)-L)(micro-H)] (LH=phenanthridine, 1; 5,6-benzoquinoline, 2), and [Os(3)(CO)(10)(micro(3)-eta(2)-L)(micro-H)] (LH=quinoxaline, 3) are reported. The radical anions 1(-), 2(-), and 3(-) can be prepared by both exhaustive electrolysis and partially by chemical reduction with cobaltocene and with sodium dispersion (only with sodium dispersion in the case of 3(-)). DFT calculations on 1-3 reveal that the LUMO for the electron-deficient compounds 1 and 2 involves significant contributions from both the heterocyclic ligand and the two metal atoms bridged by the ligand and the micro-hydride. The character of this orbital rationalizes the previously observed regioselective reactions of these complexes with nucleophiles. In contrast, the LUMO for the electron precise 3 involves only ligand-based orbitals. Partial chemical reduction of 1 and 2 requires an excess of either cobaltocene or sodium, and their (1)H and (13)C NMR spectra reveal selective line broadening of those proton resonances that are predicted by DFT calculations to bear the greatest amount of free spin density. The variable temperature behavior of the partially chemically reduced species of 1 and 2 indicates that electron transfer between the reduced/unreduced cluster pair and between the cobaltocene/cobaltocenium pair occurs on the NMR timescale. The radical anions of 1 and 2 prepared by exhaustive electrolysis show an EPR signal at room temperature, while the NMR signals are uniformly broadened. Compound 3 appears to be partially reduced by sodium at room temperature and shows uniformly broadened (1)H NMR resonances at room temperature that sharpen significantly at -80 degrees C. The temperature dependence of the spectra are discussed in terms of the effects of relative electron nuclear relaxation processes, chemical exchange, and the results of the DFT calculations.

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Ab initio molecular orbital study of the electronic structure and the rotational barrier of benzene in the helicopter complex Os3(CO)9(C6H6)

Cited by 21 publications

References 0 publications

Organometallic Cluster Complexes with Face-Capping Arene Ligands. 8. Nucleophilic Reactivity of Cluster Complexes with Face-Capping Arene Ligands: Metal vs Ligand Protonation

Organometallic Cluster Complexes with Face-Capping Arene Ligands. 8. Nucleophilic Reactivity of Cluster Complexes with Face-Capping Arene Ligands: Metal vs Ligand Protonation

Theoretical Studies of [Os3(CO)10(α-Diimine)]: Structures, Frontier Orbitals and Bonding

Spectroscopic and Computational Investigations of Stable Radical Anions of Triosmium Benzoheterocycle Clusters

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