Parameterization of phosphine ligands demonstrates enhancement of nickel catalysis via remote steric effects

Wu, Kevin; Doyle, Abigail G.

doi:10.1038/nchem.2741

Cited by 201 publications

(205 citation statements)

References 35 publications

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“…20–23 To date, it remains a significant challenge to quantitatively describe the catalyst-substrate dispersion interaction and distinguish it from other types of non-covalent interactions, such as steric and electrostatic effects. 24–26 Inspired by the distortion/interaction model established by Houk and Bickelhaupt, 27 herein we report a ligand-substrate interaction model for the analysis of ligand effects on the through-space and through-bond interactions between the catalyst and the substrate. Based on energy decomposition analysis 28,29 of computed transition states, this model allows for the quantitative prediction of the effects of ligand-substrate dispersion interactions on catalyst’s activity.…”

Section: Introductionmentioning

confidence: 99%

Ligand–Substrate Dispersion Facilitates the Copper-Catalyzed Hydroamination of Unactivated Olefins

et al. 2017

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Current understanding of ligand effects in transition metal catalysis is mostly based on the analysis of catalyst-substrate through-bond and through-space interactions, with the latter commonly considered to be repulsive in nature. The dispersion interaction between the ligand and the substrate, a ubiquitous type of attractive non-covalent interaction, is seldom accounted for in the context of transition metal-catalyzed transformations. Herein we report a computational model to quantitatively analyze the effects of different types of catalyst-substrate interactions on reactivity. Using this model, we show that in the copper(I) hydride (CuH)-catalyzed hydroamination of unactivated olefins, the substantially enhanced reactivity of copper catalysts based on bulky bidentate phosphine ligands originates from the attractive ligand-substrate dispersion interaction. These computational findings are validated by kinetic studies across a range of hydroamination reactions using structurally diverse phosphine ligands, revealing the critical role of bulky P-aryl groups in facilitating this process.

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Section: Introductionmentioning

confidence: 99%

Ligand–Substrate Dispersion Facilitates the Copper-Catalyzed Hydroamination of Unactivated Olefins

et al. 2017

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“…Previous studies from one of our groups 23 and others 24 have identified numerous multi-dimensional correlations between molecular parameters and reaction outcomes. The computationally derived parameters in this study only revealed relatively complex models to describe the rate measurement, the simplest of which involved four unique terms.…”

Section: Resultsmentioning

confidence: 99%

Quantitative Modeling of Bis(pyridine)silver(I) Permanganate Oxidation of Hydantoin Derivatives: Guidelines for Predicting the Site of Oxidation in Complex Substrates

et al. 2017

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The bis(pyridine)silver (I) permanganate promoted hydroxylation of diketopiperazines has served as a pivotal transformation in the synthesis of complex epipolythiodiketopiperazine alkaloids. This late-stage C–H oxidation chemistry is strategically critical to access N-acyl iminium ion intermediates necessary for nucleophilic thiolation of advanced diketopiperazines en route to potent epipolythiodiketopiperazine anticancer compounds. In this study, we develop an informative mathematical model using hydantoin derivatives as a training set of substrates by relating the relative rates of oxidation to various calculated molecular descriptors. The model prioritizes Hammett values and percent buried volume as key contributing factors in the hydantoin series while correctly predicting the experimentally observed oxidation sites in various complex diketopiperazine case studies. Thus, a method is presented by which to use simplified training molecules and resulting correlations to explain and predict reaction behavior for more complex substrates.

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“…In contrast, the P-Ni-P angle did not lead to acorrelation on the selectivity and yields,thus reinforcing the validity of the gem-dialkyl effect. [19] As depicted in Figure 3, av ariety of electronically unbiased Grignard reagents were accommodated. Finally,inascreening for additives,CsF was found to aid in preventing further isomerization.…”

Section: Angewandte Chemiementioning

confidence: 99%

Thorpe–Ingold Effect in Branch‐Selective Alkylation of Unactivated Aryl Fluorides

2018

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Presented herein is a general protocol for the alkylation of simple aryl fluorides with unbiased secondary Grignard reagents by means of nickel catalysis. This study revealed a general Thorpe-Ingold effect in the ligand backbone which confers a high degree of selectivity for the secondary carbon center in the C-C coupling event. This protocol is characterized by mild reaction conditions, robustness, and simplicity. Both electron-rich and electron-deficient aryl fluorides are suitable candidates in this transformation. Equally amenable are a variety of heterocycles, permitting the coupling without over alkylation at the electrophilic sites.

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Parameterization of phosphine ligands demonstrates enhancement of nickel catalysis via remote steric effects

Cited by 201 publications

References 35 publications

Ligand–Substrate Dispersion Facilitates the Copper-Catalyzed Hydroamination of Unactivated Olefins

Ligand–Substrate Dispersion Facilitates the Copper-Catalyzed Hydroamination of Unactivated Olefins

Quantitative Modeling of Bis(pyridine)silver(I) Permanganate Oxidation of Hydantoin Derivatives: Guidelines for Predicting the Site of Oxidation in Complex Substrates

Thorpe–Ingold Effect in Branch‐Selective Alkylation of Unactivated Aryl Fluorides

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