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1. Substrate‐Mediator Duality of 1,4‐Dicyanobenzene in Electrochemical C(sp 2 )−C(sp 3 ) Bond Formation with Alkyl Bromides

   https://doi.org/10.1002/ange.202312128  

   Johnston, Brandon ; Loh, Daniel M. ; Nocera, Daniel G. ( November 2023 , Angewandte Chemie)

   Electrochemical approaches to form C(sp²)−C(sp³) bonds have focused on coupling C(sp³) electrophiles that form stabilized carbon‐centered radicals upon reduction or oxidation. Whereas alkyl bromides are desirable C(sp³) coupling partners owing to their availability and cost‐effectiveness, their tendency to undergo radical‐radical homocoupling makes them challenging substrates for electroreductive cross‐coupling. Herein, we disclose a metal‐free regioselective cross‐coupling of 1,4‐dicyanobenzene, a useful precursor to aromatic nitriles, and alkyl bromides. Alkyl bromide reduction is mediated directly by 1,4‐dicyanobenzene radical anions, leading to negligible homocoupling and high cross‐selectivity to form 1,4‐alkyl cyanobenzenes. The cross‐coupling scheme is compatible with oxidatively sensitive and acidic functional groups such as amines and alcohols, which have proven difficult to incorporate in alternative electrochemical approaches using carboxylic acids as C(sp³) precursors.

    

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2. Electro/Ni Dual‐Catalyzed Decarboxylative C(sp 3 )−C(sp 2 ) Cross‐Coupling Reactions of Carboxylates and Aryl Bromide

   https://doi.org/10.1002/ange.202403844  

   Luo, Jian ; Davenport, Michael T. ; Ess, Daniel H. ; Liu, T. Leo ( April 2024 , Angewandte Chemie)

   Paired redox‐neutral electrolysis offers an attractive green platform for organic synthesis by avoiding sacrificial oxidants and reductants. Carboxylates are non‐toxic, stable, inexpensive, and widely available, making them ideal nucleophiles for C−C cross‐coupling reactions. Here, we report the electro/Ni dual‐catalyzed redox‐neutral decarboxylative C(sp³)−C(sp²) cross‐coupling reactions of pristine carboxylates with aryl bromides. At a cathode, a Ni^II(Ar)(Br) intermediate is formed through the activation of Ar−Br bond by a Ni^I‐bipyridine catalyst and subsequent reduction. At an anode, the carboxylates, including amino acid, benzyl carboxylic acid, and 2‐phenoxy propionic acid, undergo oxidative decarboxylation to form carbon‐based free radicals. The combination of Ni^II(Ar)(Br) intermediate and carbon radical results in the formation of C(sp³)−C(sp²) cross‐coupling products. The adaptation of this electrosynthesis method to flow synthesis and valuable molecule synthesis was demonstrated. The reaction mechanism was systematically studied through electrochemical voltammetry and density functional theory (DFT) computational studies. The relationships between the electrochemical properties of carboxylates and the reaction selectivity were revealed. The electro/Ni dual‐catalyzed cross‐coupling reactions described herein expand the chemical space of paired electrochemical C(sp³)−C(sp²) cross‐coupling and represent a promising method for the construction of the C(sp³)−C(sp²) bonds because of the ubiquitous carboxylate nucleophiles and the innate scalability and flexibility of electrochemical flow‐synthesis technology.

    

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3. Cobalt−NHC Catalyzed C(sp 2 )−C(sp 3 ) and C(sp 2 )−C(sp 2 ) Kumada Cross‐Coupling of Aryl Tosylates with Alkyl and Aryl Grignard Reagents

   https://doi.org/10.1002/cctc.202001347  

   Piontek, Aleksandra ; Ochędzan‐Siodłak, Wioletta ; Bisz, Elwira ; Szostak, Michal ( November 2020 , ChemCatChem)

   The first cobalt‐catalyzed cross‐coupling of aryl tosylates with alkyl and aryl Grignard reagents is reported. The catalytic system uses CoF₃and NHCs (NHC=N‐heterocyclic carbene) as ancillary ligands. The reaction proceeds via highly selective C−O bond functionalization, leading to the corresponding products in up to 98 % yield. The employment of alkyl Grignard reagents allows to achieve a rare C(sp²)−C(sp³) cross‐coupling of C−O electrophiles, circumventing isomerization and β‐hydride elimination problems. The use of aryl Grignards leads to the formation of biaryls. The C−O cross‐coupling sets the stage for a sequential cross‐coupling by exploiting the orthogonal selectivity of the catalytic system.

    

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4. Nickel‐Catalyzed C( sp 2 )−C( sp 3 ) Kumada Cross‐Coupling of Aryl Tosylates with Alkyl Grignard Reagents

   https://doi.org/10.1002/adsc.201801586  

   Piontek, Aleksandra ; Ochędzan‐Siodłak, Wioletta ; Bisz, Elwira ; Szostak, Michal ( April 2019 , Advanced Synthesis & Catalysis)

   Aryl tosylates are an attractive class of electrophiles for cross‐coupling reactions due to ease of synthesis, low price, and the employment of C−O electrophiles, however, the reactivity of aryl tosylates is low. Herein, we report the Ni‐catalyzed C(sp²)−C(sp³) Kumada cross‐coupling of aryl tosylates with primary and secondary alkyl Grignard reagents. The method delivers valuable alkyl arenes by cross‐coupling with challenging alkyl organometallics possessing β‐hydrogens that are prone to β‐hydride elimination and homo‐coupling. The reaction is catalyzed by an air‐ and moisture stable‐Ni(II) precatalyst. A broad range of electronically‐varied aryl tosylates, including bis‐tosylates, underwent this transformation, and many examples are suitable at mild room temperature conditions. The combination of Ar−X cross‐coupling with the facile Ar−OH activation/cross‐coupling strategy permits for orthogonal cross‐coupling with challenging alkyl organometallics. Furthermore, we demonstrate that the method operates with TON reaching 2000, which is one of the highest turnovers observed to date in Ni‐catalyzed cross‐couplings.

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5. Iron‐Catalyzed C( sp 2 )−C( sp 3 ) Cross‐Coupling of Chlorobenzamides with Alkyl Grignard Reagents: Development of Catalyst System, Synthetic Scope, and Application

   https://doi.org/10.1002/adsc.201800849  

   Bisz, Elwira ; Szostak, Michal ( November 2018 , Advanced Synthesis & Catalysis)

   Direct preparation of alkylated amide‐derivatives by cross‐coupling chemistry using sustainable protocols is challenging due to sensitivity of the amide functional group to reaction conditions. Herein, we report the synthesis of alkyl‐substituted amides by iron‐catalyzed C(sp²)−C(sp³) cross‐coupling of Grignard reagents with aryl chlorides. The products of these reactions are broadly used in the synthesis of pharmaceuticals, agrochemicals and other biologically‐active molecules. Furthermore, amides are used as versatile intermediates that can participate in the synthesis of valuable ketones and amines, providing access to motifs of broad synthetic interest. The reaction is characterized by its good substrate scope, tolerating a range of amide substitution, including sterically‐bulky, sensitive and readily modifiable amides. The reaction is compatible with challenging organometallics possessing β‐hydrogens, and proceeds under very mild, operationally‐simple conditions. Optimization of the catalyst system demonstrated the beneficial effect of O‐coordinating ligands on the cross‐coupling. The reaction was found to be fully chemoselective for the mono‐substitution at the less sterically‐hindered position. Mechanistic studies establish the order of reactivity and provide insight into the role of amide to control mono‐selectivity of the alkylation. The protocol provides the possibility for convenient access to alkyl‐amide structural building blocks using sustainable cross‐coupling conditions with high efficiency.

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