Terminal Phosphido Complexes of the Ru(η<sup>5</sup>-Cp*) Fragment

Yang, Juncong; Langis-Barsetti, Sophie; Parkin, Hayley C.; McDonald, Robert; Rosenberg, Lisa

doi:10.1021/acs.organomet.9b00266

Cited by 8 publications

(7 citation statements)

References 38 publications

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“…CDCl 3 (99.8 %), DCM-d 2 , and acetone-d 6 , were obtained from Cambridge Isotope Laboratories. P Cy 2 N Ph 2 , [25] [RuCl(Cp*)(PPh 3 ) 2 ], [26] [Ru(Cp)(P tÀ Bu 2 N Ph 2 )(MeCN)]PF 6 (1 a), [8c] [Ru(Cp)(P tÀ Bu 2 N Ph 2 )(MeCN)]PF 6 (1 c), [8c] and [Ru(Cp*)(P tÀ Bu 2 N Ph 2 )(MeCN)]PF 6 (2 a) [8c] were synthesized following literature procedures and the 1 H and 31 P{ 1 H} spectroscopic data matched literature values. Dry and degassed tetrahydrofuran (THF), diethyl ether (Et 2 O), and acetonitrile (MeCN) were obtained from an Innovative Technology 400-5 Solvent purification system and stored under N 2 .…”

Section: Methodsmentioning

confidence: 99%

Origin of Stability and Inhibition of Cooperative Alkyne Hydrofunctionalization Catalysts

2021

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New entries to the [Ru(Cp/Cp*)(P R 2 N R' 2 )(MeCN)]PF 6 catalyst family were synthesized, including a Cp complex (R=Cy; R'=Ph) and two Cp* complexes (R=Cy, Ph; R'=Ph). These and other derivatives were used for the intramolecular hydroamination of 2-ethynylaniline to elucidate trends in catalytic lifetime and rate. The readily accessible [Ru(Cp)(P Cy 2 N Ph 2 )(MeCN)]PF 6 derivative showed comparable lifetime to [Ru(Cp)(P tÀ Bu 2 N Ph 2 )(MeCN)] PF 6 , the previous optimal catalyst. Donor-free 'active' catalysts, [Ru(Cp/Cp*)(P Cy 2 N Ph 2 )]PF 6 , were prepared and their thermal stability was assessed. The relatively high stability of the Cp derivative was explained by the capacity of the P Cy 2 N Ph 2 ligand to coordinate in a k 3 -(P,P,Ar) mode, which protects the lowcoordinate species. This coordination mode is inaccessible with the Cp* derivative. Additionally, [Ru(Cp*)(P Cy 2 N Ph 2 )]PF 6 readily activated the CÀ Cl bond of the solvent dichloromethane. Variable time normalization analysis (VTNA) revealed that the indole product inhibited the catalyst [Ru(Cp)(P Cy 2 N Ph 2 )(MeCN)] PF 6 , which slowed catalytic rates.

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Section: Methodsmentioning

confidence: 99%

Origin of Stability and Inhibition of Cooperative Alkyne Hydrofunctionalization Catalysts

2021

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“…Our previous studies of the generation and reactivity of Ru(η 5 -Cp*) phosphido complexes demonstrated increased substitutional lability relative to the analogous indenyl complexes due to the greater electron density at Ru and increased steric crowding from the Cp* ligand . This lability presents an opportunity for increasing the rate of turnover-limiting product substitution in catalysis, relative to the indenyl system, although it can make it challenging to isolate discrete mixed ligand complexes, since “simple” ligand-exchange reactions often lead to inseparable equilibrium mixtures of complexes resulting from variable degrees of substitution.…”

Section: Resultsmentioning

confidence: 99%

“…This lability presents an opportunity for increasing the rate of turnover-limiting product substitution in catalysis, relative to the indenyl system, although it can make it challenging to isolate discrete mixed ligand complexes, since “simple” ligand-exchange reactions often lead to inseparable equilibrium mixtures of complexes resulting from variable degrees of substitution. Phosphido ligands at the Ru(η 5 -Cp*) core are also more basic, or nucleophilic, than those at Ru(η 5 -indenyl), which is likely to enhance the rate of the (already fast) conjugate addition step in catalysis relative to the indenyl system. However, collectively, these features (increased substitutional lability and P-basicity) precluded isolation of the direct Cp* analogue of 1 , even with the mixed phosphine precursor Ru(η 5 -Cp*)Cl(PPh 2 H)(PPh 3 ) in hand (Scheme ).…”

Section: Resultsmentioning

confidence: 99%

Mechanism and Catalyst Design in Ru-Catalyzed Alkene Hydrophosphination

et al. 2022

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A thorough experimental examination of a series of half-sandwich Ru indenyl complexes [Ru(η5-indenyl)(PPh2)(L)(PPh3) (L = PPh2H, CO, NCPh)] in the catalytic hydrophosphination of tert-butyl acrylate by diphenylphosphine provides valuable lessons for the design of active and robust catalysts for this important P–C bond-forming reaction. Evidence for each fundamental step in the relevant catalytic cycles was gathered from reaction monitoring (1H and 31P NMR), kinetic analyses, stoichiometric control reactions, and the isolation and spectroscopic identification of key intermediates, catalyst deactivation products, and off-cycle byproducts. For L = PPh2H, two distinct catalytic cycles each rely on the outer-sphere, conjugate addition of the Ru–PPh2 ligand at the electron-deficient alkene. The cycles differ in their P–H activation steps (intra- vs intermolecular) but are connected by a common resting state [Ru(η5-indenyl)(PPh2)P 2, where P is the hydrophosphination product Ph2PCH2CH2CO2Bu t ]. The complex with L = CO is inert to substitution by PPh2H, which precludes one of the two conjugate addition catalytic cycles. This catalyst provides critical evidence for the conjugate addition step in the form of a spectroscopically identified phospha-enolate intermediate, a long-lived species that participates in competing, off-cycle alkene oligomerization. Nitrile lability allows the complex with L = NCPh to access the same two conjugate addition cycles observed for the complex with L = PPh2H. However, the “free” benzonitrile both inhibits catalysis and participates in the formation of a deactivation product containing the 1-azaallyl fragment, which has been isolated and crystallographically characterized. Collectively, these results indicate a surprising complexity that can arise from a simple mechanistic premise for metal-mediated hydrophosphination, and demonstrate a variety of impacts of ancillary ligands on catalysis. They highlight design features that allowed us to develop a half-sandwich Ru Cp* catalyst [Ru(η5-Cp*)(PPh2)(PPh2H)2] that exhibits a 30-fold increase in hydrophosphination activity.

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“…Ruthenium phosphido complexes gave similar products on reaction with various small molecules (Lewis bases, Bronsted acids, H 2 , alkenes, and alkynes), regardless of the nature of the supporting ligand (i.e., indenyl vs Cp*; Scheme ). , For example, reaction of either 20 or 22 with ethylene gives the cycloaddition products 21 and 23 , respectively. A lower kinetic barrier with the Ind complex 20 was not apparent since both products 21 and 23 were formed within seconds.…”

Section: Influence Of Srls On Fundamental Organometallic Reactionsmentioning

confidence: 99%

Structurally-Responsive Ligands for High-Performance Catalysts

Blacquiere

2021

ACS Catal.

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Hemilabile ligands that undergo reversible changes in denticity have long been exploited to enable catalyst activation and to increase lifetime. However, this common description does not fully reflect reality with respect to the diversity of known ligand types, modes of action, and impacts on catalysis. The term structurally responsive ligand (SRL) is employed here to encompass ligands that exhibit selftuning denticity, hapticity, or versatile coordination. This Perspective covers case study examples of SRLs in catalysis and their influence on catalyst lifetime, rate, and selectivity. The examples include leading and emerging catalysts for enabling transformations, which emphasizes both the breadth and significance of this class of ligands.

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Terminal Phosphido Complexes of the Ru(η⁵-Cp*) Fragment

Cited by 8 publications

References 38 publications

Origin of Stability and Inhibition of Cooperative Alkyne Hydrofunctionalization Catalysts

Origin of Stability and Inhibition of Cooperative Alkyne Hydrofunctionalization Catalysts

Mechanism and Catalyst Design in Ru-Catalyzed Alkene Hydrophosphination

Structurally-Responsive Ligands for High-Performance Catalysts

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Terminal Phosphido Complexes of the Ru(η5-Cp*) Fragment

Cited by 8 publications

References 38 publications

Origin of Stability and Inhibition of Cooperative Alkyne Hydrofunctionalization Catalysts

Origin of Stability and Inhibition of Cooperative Alkyne Hydrofunctionalization Catalysts

Mechanism and Catalyst Design in Ru-Catalyzed Alkene Hydrophosphination

Structurally-Responsive Ligands for High-Performance Catalysts

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Product

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Terminal Phosphido Complexes of the Ru(η⁵-Cp*) Fragment