Dioxygen adducts of rhodium N-heterocyclic carbene complexes

Keske, Eric C.; Zenkina, Olena V.; Asadi, Ali; Sun, Hongsui; Praetorius, Jeremy M.; Allen, Daryl P.; Covelli, Danielle; Patrick, Brian O.; Wang, Ruiyao; Kennepohl, Pierre; James, Brian R.; Crudden, Cathleen M.

doi:10.1039/c3dt32264e

Cited by 13 publications

(4 citation statements)

References 73 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The coordination of dioxygen to transition metal complexes very often results in the formation of monodentated dioxygen adducts { 1 O 2 } or peroxo {O 2 2− } complexes. 23 In this particular case, complex 18 is better described as a tetracoordinated Rh I { 1 O 2 } 24 species whereas 19 points to a Rh III {O 2 2− } 25 hexacoordinated compound. Suitable single crystals for X-ray determination were obtained by slow diffusion of n-hexane into saturated toluene solutions of 18 and 19.…”

Section: Coordination Of Small Moleculesmentioning

confidence: 95%

Pyridine versus acetonitrile coordination in rhodium–N-heterocyclic carbene square-planar complexes

et al. 2015

View full text Add to dashboard Cite

Experimental and theoretical studies on the factors that control the coordination chemistry of N-donor ligands in square-planar complexes of the type RhCl(NHC)L(1)L(2) (NHC = N-heterocyclic carbene) are presented. The dinuclear complexes [Rh(μ-Cl)(IPr)(η(2)-olefin)]2 {IPr = 1,3-bis-(2,6-diisopropylphenyl)imidazol-2-carbene} have been reacted with different combinations of ligands including pyridine, acetonitrile, 2-pyridylacetonitrile, triphenylphosphine, tricyclohexylphosphine, carbon monoxide or molecular oxygen. In addition, the reactivity of RhCl(IPr)(PPh3)2 has also been studied. Pyridine preferentially coordinates trans to the carbene ligand whereas π-acceptor ligands (olefin, CO or PPh3) are prone to bind cis to IPr and trans to chlorido, unless steric bulk hinders the coordination of the ligand (PCy3). In contrast, acetonitrile is more labile than pyridine but is able to form complexes coordinated cis-to-IPr. Molecular dioxygen also displaces the labile cyclooctene ligand in RhCl(IPr)(η(2)-coe)(py) to give a square-planar dioxygen adduct which can be transformed into a peroxo derivative by additional coordination of pyridine. Charge decomposition analysis (CDA) shows that σ-donation values are similar for coordination at cis- or trans-IPr positions, whereas efficient π-backbonding is significantly observed at cis position being the favoured coordination site for π-acceptor ligands. The Rh-IPr rotational barrier in a series of square-planar complexes has been analysed. It has been found that the main contribution is the steric hindrance of the ancillary ligand. The presence of a π-donor ligand such as chlorido slows down the dynamic process.

show abstract

Section: Coordination Of Small Moleculesmentioning

confidence: 95%

Pyridine versus acetonitrile coordination in rhodium–N-heterocyclic carbene square-planar complexes

et al. 2015

View full text Add to dashboard Cite

show abstract

“…The specific binding mode depends on the structure of the surrounding ligands, the availability of coordination sites at the metal, and the pattern and energies of the frontier metal d-orbitals. − In monometallic complexes, the accessible oxidation states of the metal also play a role in determining the dioxygen-binding mode. ,, The traditional names of η 1 -superoxo and η 2 -peroxo structures imply 1 e – and 2 e – oxidations of the metal center, respectively. There was, however, significant debate many years ago about the appropriate assignment of the metal and dioxygen oxidation states in these adducts. ,,,,, Recently, Kennepohl and co-workers have revisited this question, using X-ray and Raman spectroscopies with DFT calculations to show that, at least in some cases, there is little charge transfer from M to O 2 in peroxo adducts. , The dioxygen-binding mode can also influence trends in dioxygen reactivity (c.f. refs , , and ), making it an important parameter to consider when designing ORR catalysts.…”

Section: Inner-sphere Orr Catalysismentioning

confidence: 99%

“…9,170,175,176,180,181 Recently, Kennepohl and co-workers have revisited this question, using X-ray and Raman spectroscopies with DFT calculations to show that, at least in some cases, there is little charge transfer from M to O 2 in peroxo adducts. 182,183 The dioxygen-binding mode can also influence trends in dioxygen reactivity (c.f. refs 168, 178, and 179), making it an important parameter to consider when designing ORR catalysts.…”

Section: Inner-sphere Orr Catalysismentioning

confidence: 99%

Oxygen Reduction by Homogeneous Molecular Catalysts and Electrocatalysts

et al. 2018

View full text Add to dashboard Cite

The oxygen reduction reaction (ORR) is a key component of biological processes and energy technologies. This Review provides a comprehensive report of soluble molecular catalysts and electrocatalysts for the ORR. The precise synthetic control and relative ease of mechanistic study for homogeneous molecular catalysts, as compared to heterogeneous materials or surface-adsorbed species, enables a detailed understanding of the individual steps of ORR catalysis. Thus, the Review places particular emphasis on ORR mechanism and thermodynamics. First, the thermochemistry of oxygen reduction and the factors influencing ORR efficiency are described to contextualize the discussion of catalytic studies that follows. Reports of ORR catalysis are presented in terms of their mechanism, with separate sections for catalysis proceeding via initial outer- and inner-sphere electron transfer to O. The rates and selectivities (for production of HO vs HO) of these catalysts are provided, along with suggested methods for accurately comparing catalysts of different metals and ligand scaffolds that were examined under different experimental conditions.

show abstract

“…Oxidation of organic substrates using molecular oxygen as a terminal oxidant is an important process in many biological processes 1 and in industrial aerobic oxidation catalysis where oxygen or air is considered as an inexpensive, “green” oxidant that produces no hazardous waste products. 2 Precious metal catalysts have been extensively used in enabling aerobic oxidation of hydrocarbon substrates or stoichiometric O 2 activation, typically based on Pt, 3 Pd, 4 Ru, 5 Rh, 6 Ir, 7 etc. At the same time, metalloenzymes capable of aerobic oxygenation typically contain more abundant first row transition metals, which led to the development of bioinspired model complexes capable of O 2 activation, most commonly based on Cu, 8 Fe, 9 Mn, 10 and Co. 11 Although Ni is known to be present at the active site of several O 2 -reactive enzymes, 12 examples of synthetic “nickel oxygenase” reactivity in which Ni complexes assist in the transfer of O-atoms from O 2 to a substrate remain scarce.…”

Section: Introductionmentioning

confidence: 99%