Comparing the Ligand Behavior of N-Heterocyclic Phosphenium and Nitrosyl Units in Iron and Chromium Complexes

Feil, Christoph M.; Hettich, Thomas; Beyer, Katharina; Sondermann, Christina; Schlindwein, Simon H.; Nieger, Martin; Gudat, Dietrich

doi:10.1021/acs.inorgchem.9b00737

Cited by 21 publications

(14 citation statements)

References 59 publications

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“…Cis ‐ and trans ‐ 2 a , b show diagnostic downfield 31 P{ 1 H} chemical shifts for signals due to the new phosphenium ligand ( δ =440–441 ppm). The observed preference for trans versus cis geometry in 2 a , b is consistent with the established strong π‐acidity of phosphenium ligands, [15, 17b, 18a, 19, 20] since a trans structure ensures that PR 2 + does not compete with CO ligands for π‐backbonding at a Mo‐based d‐orbital [21] . X‐ray diffraction analysis of crystals of 2 b confirmed the solid state structure of the trans isomer (Figure 1), with bond angles at the phosphenium (P2) consistent with planarity at this sp 2 ‐hybridized center, and a short Mo‐P2 distance of 2.29 Å, relative to the Mo‐phosphine (P1) distance of 2.52 Å.…”

Section: Resultssupporting

confidence: 65%

Reversible Silylium Transfer between P‐H and Si‐H Donors

et al. 2020

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The Mo=PR2 π* orbital in a Mo phosphenium complex acts as acceptor in a new PIII‐based Lewis superacid. This Lewis acid (LA) participates in electrophilic Si‐H abstraction from E3SiH to give a Mo‐bound secondary phosphine ligand, Mo‐PR2H. The resulting Et3Si+ ion remains associated with the Mo complex, stabilized by η1‐P‐H donation, yet undergoes rapid exchange with an η1‐Si‐H adduct of free silane in solution. The equilibrium between these two adducts presents an opportunity to assess the role of this new LA in catalytic reactions of silanes: is the LA acting as a catalyst or as an initiator? Preliminary results suggest that a cycle including the Mo‐bound phosphine‐silylium adduct dominates in the catalytic hydrosilylation of acetophenone, relative to a putative cycle involving the silane‐silylium adduct or “free” silylium.

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Section: Resultssupporting

confidence: 65%

Reversible Silylium Transfer between P‐H and Si‐H Donors

et al. 2020

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“…[14][15][16][17][18] The possibility to describe NHP + /NHPligands in these two states makes them comparable to nitrosyls (NO + /NO -) and makes assigning formal oxidation states to the metals and exact electronic descriptions to the redox active ligand abstruse, culminating in a covalent bonding situation where formal oxidation states have lost their significance. [19,20] The notable advantage of NHP + ligands over nitrosyls is that they are sterically and electronically tunable, by changing the N-substituents or the backbone. Due to the inverted binding properties of NHP + ligands, the tunability of their steric and electronic properties and the potential interconversion to the formally NHPstate, NHP's bound to metal fragments could display different reactivities and open many new potential applications if studied in more depth.…”

Section: Introductionmentioning

confidence: 99%

“…[14][15][16][17][18] The possibility to describe NHP + /NHPligands in these two states makes them comparable to nitrosyls (NO + /NO -) and makes assigning formal oxidation states to the metals and exact electronic descriptions to the redox active ligand abstruse, culminating in a covalent bonding situation where formal oxidation states have lost their significance. [19,20] The nota-dimer [(PPP)Rh(CN t Bu)] 2 (5). Analysis of the solid-state structures and computational studies have provided insight into the electronic structure and bonding in 3-5, revealing that the NHP +/fragments in 3, 4, and 5 are best described using an NHP -/Rh I description.…”

Section: Introductionmentioning

confidence: 99%

N‐Heterocyclic Phosphido Complexes of Rhodium Supported by a Rigid Pincer Ligand

et al. 2020

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The diphosphine, N-heterocyclic phosphenium (NHP + ) /phosphido (NHP -) containing ligand (PPP +/-) has been coordinated to rhodium to study the coordination chemistry of group 9 metals and NHP +/fragments. Addition of the chlorophosphine ligand PP Cl P to [Rh(COD)Cl]2 produces the complex (PP Cl P)RhCl ( 2), which can be reduced to form (PPP)RhPMePh2 (3), the asymmetric dimer [(PPP)Rh]2 (4) and the asymmetric dimer [(PPP)Rh(CN t Bu)]2 (5). Analysis of the solid-state structures and computational studies have provided insight into the electronic structure and bonding in 3-5, revealing that the NHP +/fragments in 3, 4 and 5 are best described using an NHP -/Rh I description. Both 3 and 5 were found to be reactive towards the S-H bond of thiophenol, generating (PPP)RhSPh ( 6) and (PPP)Rh(SPh)(CN t Bu) ( 7) respectively.

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“…Alternatively, a pyramidal geometry about the phosphorus center may indicate two-electron reduction of the NHP + ligand to an anionic NHP – phosphido moiety, leading to a more covalent M–P NHP bond. The two binding modes of NHP +/− s and ambiguity in metal formal oxidation states that ensues draw to mind an interesting analogy to nitrosyl ligands (NO +/0/‑ ) ligands in their coordination chemistry, allowing NHP +/− s to be considered as tunable versions of NO +/0/– . , …”

Section: Introductionmentioning

confidence: 99%

A Series of Dimeric Cobalt Complexes Bridged by N-Heterocyclic Phosphido Ligands

et al. 2020

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A tridentate [PPP] ligand has been used to construct a series of dimeric cobalt complexes and explore cooperative multielectron redox processes that are both metal- and ligand-centered. Reduction of (PPClP)CoCl2 (1) with excess magnesium affords the CoICoI N-heterocyclic phosphido (NHP–)-bridged symmetric dimer [(μ-PPP)Co]2 (2). Two-electron oxidation of 2 with FcPF6 generates an asymmetrically bridged dication [(μ-PPP)Co]2[PF6]2 (3) in which the oxidation has occurred in a delocalized fashion throughout the Co2P2 core. In contrast, [(μ-PPP)Co]2 + (5), which can be generated either by one-electron oxidation of 2 with FcPF6 or comportionation of 2 and 3, features an asymmetric geometry and localized mixed valence. Treatment of 1 with the milder reductants CoCp2 and KBEt3H does not lead to formation of 2, 3, or 5 but instead generates dimeric species [(PPP)CoCl]2 (6) and [(PPP)CoH]2 (7). Unlike 2–5, where the phosphine side arms of the tridentate [PPP] ligand span the two Co centers, complex 6 and 7 are connected solely by NHP– ligands that bridge the two (PPP)Co fragments.

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Comparing the Ligand Behavior of N-Heterocyclic Phosphenium and Nitrosyl Units in Iron and Chromium Complexes

Cited by 21 publications

References 59 publications

Reversible Silylium Transfer between P‐H and Si‐H Donors

Reversible Silylium Transfer between P‐H and Si‐H Donors

N‐Heterocyclic Phosphido Complexes of Rhodium Supported by a Rigid Pincer Ligand

A Series of Dimeric Cobalt Complexes Bridged by N-Heterocyclic Phosphido Ligands

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