Robert H. Crabtree scite author profile

We now look in detail at compounds with multiple bonds between metal and ligand. We are chiefly concerned with multiple bonds to carbon, as in metal carbene complexes L n M=CR 2 , which have a trigonal planar carbon and at least formally contain an M=C double bond, and metal carbyne complexes, L n M≡CR, which are linear and contain an M≡C triple bond, but we also look at complexes with multiple bonds to O and N. These are more often actor rather than spectator ligands. CARBENESA free carbene such as CH 2 has two spin states, singlet (↑↓) and triplet (↑↑). These are distinct spin isomers with different H−C−H angles and not just resonance forms, which always have the same spin. In the singlet, the electrons are paired up in the sp 2 lone pair, but in the triplet there is one electron in each of the sp 2 and p orbitals. (Fig. 11.1a). Unlike many of the ligands discussed in earlier chapters, carbenes are rarely stable in the free state. Methylene, :CH 2 , for example, is a transient intermediate that reacts rapidly with a wide variety of species, even alkanes. This instability (both thermodynamic and kinetic) contributes to the very strong binding of carbenes to metal atoms by disfavoring dissociation.

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A Functional Model for O-O Bond Formation by the O ₂ -Evolving Complex in Photosystem II

Limburg

Vrettos

Liable‐Sands

et al. 1999

Science

703

640

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The formation of molecular oxygen from water in photosynthesis is catalyzed by photosystem II at an active site containing four manganese ions that are arranged in di-mu-oxo dimanganese units (where mu is a bridging mode). The complex [H2O(terpy)Mn(O)2Mn(terpy)OH2](NO3)3 (terpy is 2,2':6', 2"-terpyridine), which was synthesized and structurally characterized, contains a di-mu-oxo manganese dimer and catalyzes the conversion of sodium hypochlorite to molecular oxygen. Oxygen-18 isotope labeling showed that water is the source of the oxygen atoms in the molecular oxygen evolved, and so this system is a functional model for photosynthetic water oxidation.

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Defining the hydrogen bond: An account (IUPAC Technical Report)

Arunan

Desiraju

Klein³

et al. 2011

917

622

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Abstract:The term "hydrogen bond" has been used in the literature for nearly a century now. While its importance has been realized by physicists, chemists, biologists, and material scientists, there has been a continual debate about what this term means. This debate has intensified following some important experimental results, especially in the last decade, which questioned the basis of the traditional view on hydrogen bonding. Most important among them are the direct experimental evidence for a partial covalent nature and the observation of a blue-shift in stretching frequency following X-HؒؒؒY hydrogen bond formation (XH being the hydrogen bond donor and Y being the hydrogen bond acceptor). Considering the recent experimental and theoretical advances, we have proposed a new definition of the hydrogen bond, which emphasizes the need for evidence. A list of criteria has been provided, and these can be used as evidence for the hydrogen bond formation. This list is followed by some characteristics that are observed in typical hydrogen-bonding environments.

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Half-Sandwich Iridium Complexes for Homogeneous Water-Oxidation Catalysis

et al. 2010

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Iridium half-sandwich complexes of the types Cp*Ir(N-C)X, [Cp*Ir(N-N)X]X, and [CpIr(N-N)X]X are catalyst precursors for the homogeneous oxidation of water to dioxygen. Kinetic studies with cerium(IV) ammonium nitrate as primary oxidant show that oxygen evolution is rapid and continues over many hours. In addition, [Cp*Ir(H(2)O)(3)]SO(4) and [(Cp*Ir)(2)(μ-OH)(3)]OH can show even higher turnover frequencies (up to 20 min(-1) at pH 0.89). Aqueous electrochemical studies on the cationic complexes having chelate ligands show catalytic oxidation at pH > 7; conversely, at low pH, there are no oxidation waves up to 1.5 V vs NHE for the complexes. H(2)(18)O isotope incorporation studies demonstrate that water is the source of oxygen atoms during cerium(IV)-driven catalysis. DFT calculations and kinetic experiments, including kinetic-isotope-effect studies, suggest a mechanism for homogeneous iridium-catalyzed water oxidation and contribute to the determination of the rate-determining step. The kinetic experiments also help distinguish the active homogeneous catalyst from heterogeneous nanoparticulate iridium dioxide.

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