Site‐Selective Electrochemical Benzylic C−H Amination

Hou, Zhufeng; Liu, Dingjin; Xiong, Peng; Lai, Xiao‐Li; Song, Jinshuai; Xu, Hai‐Chao

doi:10.1002/ange.202013478

Cited by 99 publications

(12 citation statements)

References 59 publications

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“…Continuing their interest in C−N bond formation via electrochemical C−H amination reactions, [195] Xu′s research group recently developed a metal‐ and external oxidant‐free method to construct a C−N bond from site‐selective electrochemical benzylic C−H bond amination reaction (Scheme 95). [196] …”

Section: C−h Bond Aminationmentioning

confidence: 99%

Cross‐Coupling of C−H and N−H Bonds: A Hydrogen Evolution Strategy for the Construction of C−N Bonds

et al. 2022

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The progress in CÀ N bond construction is significant in synthetic and biological chemistry. Cross-dehydrogenative couplings of CÀ H and NÀ H motifs serve as a unique class of the most atom-economical and straightforward strategies for constructing CÀ N bonds. Herein, we enclosed the most updated methodologies developed in the assembly of CÀ N bonds via photo-catalyzed, transition-metal-catalyzed, electrochemical, and metal-free amination and amidation reactions of saturated and unsaturated CÀ H bonds. Compared with the well-established transition-metal-catalyzed protocols, electricity, or visible light-mediated amination and amidation reactions are competent and appealing. Plausible mechanistic pathways are also described in representative amidation and amination reactions to provide insights for the future development of environmentally kind processes.

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Section: C−h Bond Aminationmentioning

confidence: 99%

Cross‐Coupling of C−H and N−H Bonds: A Hydrogen Evolution Strategy for the Construction of C−N Bonds

et al. 2022

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“…While access to carbocation intermediates may be accomplished electrochemically, contemporary methodologies are largely limited by the high overpotential required for reactivity, thereby restricting the scope of amenable C(sp 3 )-H and nucleophile coupling partners. 32,33 Whereas C(sp 3 )-H functionalization via HAT-ORPC has been proposed in a recent study from Liu and Chen, the method uses a strong, stoichiometric oxidant and solvent quantities of nucleophile. 7 Here we report a HAT-ORPC platform for C(sp 3 )-H functionalization using a mild, commercially available N-acyloxyphthalimide as HAT precursor.…”

Section: H Mementioning

confidence: 99%

“…Notably, 4-pyridyl diphenylmethane underwent fluorination in 63% yield, demonstrating tolerance to a valuable Nheterocycle scaffold (31). 52 Other heterocycles such as thiophenes, furans, and thiazoles were also tolerated under the reaction conditions (32)(33)(34)(35). Since many bioactive compounds contain heterocyclic fragments, this observation prompted us to evaluate the method for the late-stage derivatization of various pharmaceuticals and complex molecules.…”

Section: % Yieldmentioning

confidence: 99%

A General Strategy for C(sp3)–H Functionalization with Nucleophiles Using Methyl Radical as a Hydrogen Atom Abstractor

Leibler¹,

Tekle‐Smith²,

Doyle

2021

Preprint

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We have developed a photocatalytic method that employs widely available, low-cost nucleophiles and a readily accessible HAT precursor for C(sp<sup>3</sup>)–H fluorination, chlorination, etherification, thioetherification, azidation, and carbon–carbon bond formation. Mechanistic studies are consistent with methyl radical-mediated HAT and linear free-energy relationships suggest that radical oxidation influences site-selectivity. Furthermore, this approach was highly effective for the construction of multi-halogenated scaffolds and the late-stage functionalization of several bioactive molecules and pharmaceuticals with tunable regioselectivity.

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“…More recently, Xu reported on the electro-catalyzed benzylic C−H amination. 60 Within our program on sustainable C−H activation, 35−37 we have now devised the first electrochemical oxidative intermolecular allylic C(sp 3 )−H aminations (Scheme 1c). Salient features of our findings include the following: (1) transition-metal-free conditions, (2) absence of chemical oxidants, (3) electric current as the sole oxidant, and (4) a user-friendly undivided cell setup.…”

Section: Introductionmentioning

confidence: 99%

Electro-oxidative Intermolecular Allylic C(sp³)–H Aminations

et al. 2021

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The oxidative intermolecular nitrogenation of C(sp 3 )−H bonds represents one of the most straightforward strategies to construct nitrogen-containing molecules. However, a sacrificial chemical oxidant is generally required. Herein, we describe electrochemical oxidative intermolecular allylic C(sp 3 )−H aminations in an undivided cell by electric current. The cross-dehydrogenative amination proceeded efficiently with ample scope under metal-and chemical oxidant-free reaction conditions, giving molecular H 2 as the only byproduct.

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Site‐Selective Electrochemical Benzylic C−H Amination

Cited by 99 publications

References 59 publications

Cross‐Coupling of C−H and N−H Bonds: A Hydrogen Evolution Strategy for the Construction of C−N Bonds

Cross‐Coupling of C−H and N−H Bonds: A Hydrogen Evolution Strategy for the Construction of C−N Bonds

A General Strategy for C(sp3)–H Functionalization with Nucleophiles Using Methyl Radical as a Hydrogen Atom Abstractor

Electro-oxidative Intermolecular Allylic C(sp³)–H Aminations

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Site‐Selective Electrochemical Benzylic C−H Amination

Cited by 99 publications

References 59 publications

Cross‐Coupling of C−H and N−H Bonds: A Hydrogen Evolution Strategy for the Construction of C−N Bonds

Cross‐Coupling of C−H and N−H Bonds: A Hydrogen Evolution Strategy for the Construction of C−N Bonds

A General Strategy for C(sp3)–H Functionalization with Nucleophiles Using Methyl Radical as a Hydrogen Atom Abstractor

Electro-oxidative Intermolecular Allylic C(sp3)–H Aminations

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Electro-oxidative Intermolecular Allylic C(sp³)–H Aminations