Design and Application of a Screening Set for Monophosphine Ligands in Cross-Coupling

Gensch, Tobias; Smith, Spencer; Colacot, Thomas J.; Timsina, Yam N.; Xu, Guolin; Glasspoole, Ben W.; Sigman, Matthew S.

doi:10.1021/acscatal.2c01970

Cited by 32 publications

(34 citation statements)

References 41 publications

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“…Ligand parametrization for predicting the outcome of a catalytic reaction with the help of data science is emerging as a new tool in organic synthesis. − Although the Tolman cone angle , descriptor has been of great value in understanding and predicting ligand properties in catalysis, it suffers from certain drawbacks, one of which is not taking ligand flexibility into consideration. − Recently, the groups of Sigman and Doyle reported that the use of a single descriptor, minimum percent buried volume or % V bur (min), could nicely predict the ligation state of the catalytically active complexes in both Pd- and Ni-catalyzed reactions . Initially, the authors were inspired by the high efficiency of the DinoPhos ligand family (TyrannoPhos and TriceraPhos) in the Ni-catalyzed coupling reaction of acetal and boroxine (Scheme ).…”

Section: Role Of the Ligands In Forming The L1pd(0) Precatalyst In Situmentioning

confidence: 99%

Emerging Trends in Cross-Coupling: Twelve-Electron-Based L₁Pd(0) Catalysts, Their Mechanism of Action, and Selected Applications

Firsan¹,

Sivakumar

Colacot³

2022

Chem. Rev.

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Monoligated palladium(0) species, L1Pd(0), have emerged as the most active catalytic species in the cross-coupling cycle. Today, there are methods available to generate the highly active but unstable L1Pd(0) catalysts from stable precatalysts. While the size of the ligand plays an important role in the formation of L1Pd(0) during in situ catalysis, the latter can be precisely generated from the precatalyst by various technologies. Computational, kinetic, and experimental studies indicate that all three steps in the catalytic cycleoxidative addition, transmetalation, and reductive eliminationcontain monoligated Pd. The synthesis of precatalysts, their mode of activation, application studies in model systems, as well as in industry are discussed. Ligand parametrization and AI based data science can potentially help predict the facile formation of L1Pd(0) species.

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Section: Role Of the Ligands In Forming The L1pd(0) Precatalyst In Situmentioning

confidence: 99%

Emerging Trends in Cross-Coupling: Twelve-Electron-Based L₁Pd(0) Catalysts, Their Mechanism of Action, and Selected Applications

Firsan¹,

Sivakumar

Colacot³

2022

Chem. Rev.

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“…As showcased below, the designer maps can be applied to various downstream data science steps in multi-objective optimization campaigns. In addition to the reaction optimization applications presented (vide infra), it can be envisioned that this calculated parameter library and chemical space map could be used for many other potential applications such as training set design, novel ligand generation, and mechanistic understanding …”

Section: Resultsmentioning

confidence: 99%

Data-Driven Multi-Objective Optimization Tactics for Catalytic Asymmetric Reactions Using Bisphosphine Ligands

Dotson

Dijk

Timmerman³

et al. 2022

J. Am. Chem. Soc.

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Optimization of the catalyst structure to simultaneously improve multiple reaction objectives (e.g., yield, enantioselectivity, and regioselectivity) remains a formidable challenge. Herein, we describe a machine learning workflow for the multi-objective optimization of catalytic reactions that employ chiral bisphosphine ligands. This was demonstrated through the optimization of two sequential reactions required in the asymmetric synthesis of an active pharmaceutical ingredient. To accomplish this, a density functional theory-derived database of >550 bisphosphine ligands was constructed, and a designer chemical space mapping technique was established. The protocol used classification methods to identify active catalysts, followed by linear regression to model reaction selectivity. This led to the prediction and validation of significantly improved ligands for all reaction outputs, suggesting a general strategy that can be readily implemented for reaction optimizations where performance is controlled by bisphosphine ligands.

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“…Remarkably, heteroaryl tosylate coupling at room temperature without any reduction in the product yield was also demonstrated. Recently, Sigman used the Pd 2 (dba) 3 / CM-phos catalyst system for the SMC of aryl chlorides, aryl triflates, and sterically hindered aryl bromides …”

Section: Cm-phos-type Monophosphorus Ligandsmentioning

confidence: 99%

“…Recently, Sigman used the Pd 2 (dba) 3 /CM-phos catalyst system for the SMC of aryl chlorides, aryl triflates, and sterically hindered aryl bromides. 15 In addition to arylboronic acids, other boronic acid surrogates such as trifluoroborate salts and pinacol boronate esters were coupled smoothly with good yields. 13,14 The coupling of aryl mesylates with potassium (hetero)aryl-, alkyl-, and vinyl-trifluoroborate salts was also successfully accom-plished (Scheme 5B).…”

Section: Suzuki−miyaura Couplingmentioning

confidence: 99%

Facile Assembly of Modular-Type Phosphines for Tackling Modern Arylation Processes

2022

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Conspectus This Account presents an overview of a promising collection of phosphine ligands simply made from the modular Fischer indolization process and their applications in modern arylation processes. Using one easily accessible 2-arylindole scaffold, three major phosphino-moiety-positioned ligand series can be readily generated. We have attempted to explore challenging electrophilic and nucleophilic partners for the coupling reaction using the modular ligand tool. For the electrophilic partner study, CM-phos-type ligands, where the phosphino group is located at the 2-arene position of 2-arylindole, allow the successful cross-coupling of aryl mesylates. The CM-phos ligand forms a palladacycle before entering the cross-coupling catalytic cycle. For the nucleophilic partner investigation, the indole C3-positioned phosphines show the first accomplishment of Pd-catalyzed organotitanium nucleophile arylation. Indeed, the aryl-titanium nucleophile undergoes cross-coupling more efficiently than does the organoboron coupling partner in particular cases. Moreover, in the indole C3-positioned phosphine series, the −PPh2-containing ligands perform better in the highly sterically hindered cross-coupling of aryl chlorides than do ligands containing the −PCy2 moiety. The catalyst loading can even be reduced to 0.2 mol % Pd for tetra-ortho-substituted biaryl synthesis. This finding offers a new perspective on the next-generation design of phosphine ligands in which the sterically bulky and electron-rich −PR2 group (R = alkyl) may not be necessary for the cross-coupling of aryl chlorides. In general, we hypothesize that a good balance of steric and electronic properties for entertaining the oxidative addition and reductive elimination steps is crucial to the success of the reaction. For the steric factor, the highly sterically congested −PR2 group normally favors the reductive elimination, yet we conjecture that this sterically bulky group would serve as an obstacle for the incoming aryl halides. For the electronic factor, the electron rich −PR2 group is believed to support the oxidative cleavage of the C(Ar)–Cl bond by donating more electron density to the corresponding σ* orbital. Nevertheless, the high electron richness of the −PR2 group may disfavor the reductive elimination electronically. Overall, an appropriate balance of both electron density and steric bulkiness is suggested to allow the sterically hindered cross-coupling to proceed smoothly. We have found that the −PPh2-containing ligand is a good starting point for this investigation. The formation of aromatic carbon–carbon (C–C) and carbon–heteroatom (C–X) bonds from aryl chlorides was successfully realized using our proprietary phosphines. In addition to the indole-core-bearing ligand skeleton, we also explored the relevant imidazolyl and carbazolyl phosphines for their unique applications. Interestingly, the carbazolyl ligand, having more flexible C–N axial chirality, displays particular interchangeable Pd–N and Pd–arene coordination, which facilitates both oxid...

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Design and Application of a Screening Set for Monophosphine Ligands in Cross-Coupling

Cited by 32 publications

References 41 publications

Emerging Trends in Cross-Coupling: Twelve-Electron-Based L₁Pd(0) Catalysts, Their Mechanism of Action, and Selected Applications

Emerging Trends in Cross-Coupling: Twelve-Electron-Based L₁Pd(0) Catalysts, Their Mechanism of Action, and Selected Applications

Data-Driven Multi-Objective Optimization Tactics for Catalytic Asymmetric Reactions Using Bisphosphine Ligands

Facile Assembly of Modular-Type Phosphines for Tackling Modern Arylation Processes

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Design and Application of a Screening Set for Monophosphine Ligands in Cross-Coupling

Cited by 32 publications

References 41 publications

Emerging Trends in Cross-Coupling: Twelve-Electron-Based L1Pd(0) Catalysts, Their Mechanism of Action, and Selected Applications

Emerging Trends in Cross-Coupling: Twelve-Electron-Based L1Pd(0) Catalysts, Their Mechanism of Action, and Selected Applications

Data-Driven Multi-Objective Optimization Tactics for Catalytic Asymmetric Reactions Using Bisphosphine Ligands

Facile Assembly of Modular-Type Phosphines for Tackling Modern Arylation Processes

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Product

Resources

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Emerging Trends in Cross-Coupling: Twelve-Electron-Based L₁Pd(0) Catalysts, Their Mechanism of Action, and Selected Applications

Emerging Trends in Cross-Coupling: Twelve-Electron-Based L₁Pd(0) Catalysts, Their Mechanism of Action, and Selected Applications