Silylboronate-Mediated Defluorosilylation of Aryl Fluorides with or without Ni-Catalyst

Zhou, Jun; Zhao, Zhengyu; Shibata, Norio

doi:10.3389/fchem.2021.771473

Cited by 7 publications

(7 citation statements)

References 49 publications

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“…In 2020, Shi et al also reported rhodium(III)-catalyzed S N Ar alkoxylation using aryl fluorides and primary alcohols, proposing a Meisenheimer-type intermediate; however, most yields were moderate (43–77% and 97%; for an example, see Scheme b) . Recently, we reported the defluorosilylation of aryl fluorides via C–F bond cleavage, wherein a silyl boronate, Et 3 Si-BPin, facilitates the selective functionalization of the C–F bonds of aryl fluorides to generate C–Si bonds on aryl silanes (Scheme c) . Based on this transformation, we envisaged alkoxy variants of Et 3 Si-Bpin, that is alkoxyboronic acid pinacol esters (RO-Bpins), as effective reagents for introducing RO groups into fluoroaromatics via selective C–F bond cleavage.…”

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Etherification of Fluoroarenes with Alkoxyboronic Acid Pinacol Esters via C–F Bond Cleavage

et al. 2022

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Potassium-base-mediated defluoroetherification of aryl and heteroaryl fluorides with alkoxyboronic acid pinacol esters under transition-metal-free conditions is reported. This protocol efficiently and safely provides a wide variety of aryl ethers in high yields without using metal catalysts, specific ligands, and harsh conditions to selectively forge Csp2–O bonds via the Csp2–F cleavage. This method can be applied to the late-stage etherification of structurally complex Csp2-fluorides and bioactive alcohols, such as β-estradiol, calciferol, and tocopherol.

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Etherification of Fluoroarenes with Alkoxyboronic Acid Pinacol Esters via C–F Bond Cleavage

et al. 2022

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“…In addition, the possible oxidative degradation mechanisms and pathways of BaP in the atmosphere have been explored by Dang et al (2015) . However, despite the involvement of transition metals in many catalytic processes ( Fujihara and Tsuji, 2019 ; Lin et al, 2021 ; Parmar et al, 2021 ; Sánchez-López et al, 2021 ; Yang et al, 2021 ; Zhou et al, 2021 ; Zhou et al, 2022 ), the use of transition metal complexes as non-sacrificial oxidants for the degradation of BaP has not been reported in the literature.…”

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confidence: 99%

The High-Effective Catalytic Degradation of Benzo[a]pyrene by Mn-Corrolazine Regulated by Oriented External Electric Field: Insight From DFT Study

et al. 2022

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The degradation of BaP into hydroxybenzo[a]pyrene by Mn-corrolazine and its regulation by an oriented external electronic field (OEEF) were systematically studied using first-principle calculations. Extensive density function calculations showed that the degradation of BaP into hydroxybenzo[a]pyrene by Mn-corrolazine occurs via a three-step process in the absence of OEEF, in which a more toxic and stable epoxide intermediate is generated. However, upon application of OEEF along the intrinsic Mn-O reaction axis, the degradation of BaP into hydroxybenzo[a]pyrene is greatly simplified. The negative charge on the terminal O atom of Mn-OO corrolazine increases with an increase in the OEEF intensity. As the intensity of the OEEF increases over 0.004 a.u., the negatively charged terminal O atom has the ability to directly abstract the positively charged H atom of BaP and the degradation of BaP into hydroxybenzo[a]pyrene can be completed via a one-step process, avoiding the production of more toxic epoxide intermediates.

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“…For instance, whereas it was almost exclusive toward the C2-silylation for quinolines having electron-neutral (alkyl or aryl groups, 2a – 2g ) or halide substituents ( 2h – 2j ), the selectivity was decreased with an electron-donating substituent ( 2k ). Noteworthy is that defluorosilylation, often encountered in the C–F bond activation by alkali bases, − was not observed under our reaction conditions ( 2i – 2j ). Additionally, a biologically relevant quinoline derivative was viable to the desired selective silaboration ( 2l ).…”

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KOtBu-Catalyzed 1,2-Silaboration of N-Heteroarenes to Access 2-Silylheterocycles: A Cooperative Model for the Regioselectivity

et al. 2022

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Reductive functionalization of N-heteroarenes offers a route to highly versatile heterocyclic synthons bearing multiple transformable groups. We present herein the development of KOtBu-catalyzed 1,2-silaboration of a broad range of N-heteroarenes, affording heterocyclic allylamines or enamines with the formation of a sp3 C2–Si bond. These labile compounds were isolated either as their N-acyl derivatives or as rearomatized 2-silyl-N-heteroarenes by the one-pot procedures. A model of the six-membered ion-pair complex was proposed to rationalize the observed 1,2-regioselectivity, wherein KOtBu catalyst plays an associative role in activating the substrate and silylborane reagent.

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Silylboronate-Mediated Defluorosilylation of Aryl Fluorides with or without Ni-Catalyst

Cited by 7 publications

References 49 publications

Etherification of Fluoroarenes with Alkoxyboronic Acid Pinacol Esters via C–F Bond Cleavage

Etherification of Fluoroarenes with Alkoxyboronic Acid Pinacol Esters via C–F Bond Cleavage

The High-Effective Catalytic Degradation of Benzo[a]pyrene by Mn-Corrolazine Regulated by Oriented External Electric Field: Insight From DFT Study

KOtBu-Catalyzed 1,2-Silaboration of N-Heteroarenes to Access 2-Silylheterocycles: A Cooperative Model for the Regioselectivity

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