Selective C(sp<sup>3</sup>)−H Aerobic Oxidation Enabled by Decatungstate Photocatalysis in Flow

Laudadio, Gabriele; Govaerts, Sebastian; Wang, Ying; Ravelli, Davide; Koolman, Hannes F.; Fagnoni, Maurizio; Djurić, Stevan W.; Noël, Timothy

doi:10.1002/anie.201800818

Cited by 194 publications

(125 citation statements)

References 82 publications

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“…[135] Thespecies generating the radical can alter the possible products formed as exemplified for sclareolide with organocatalysis (C2:C3) (Scheme 19) versus photoredox (C2:C1) (Scheme 25). [135] Thespecies generating the radical can alter the possible products formed as exemplified for sclareolide with organocatalysis (C2:C3) (Scheme 19) versus photoredox (C2:C1) (Scheme 25).…”

Section: Angewandte Chemiementioning

confidence: 99%

Catalytic Aerobic Oxidation of C(sp³)−H Bonds

2019

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Oxidation reactions are a key technology to transform hydrocarbons from petroleum feedstock into chemicals of a higher oxidation state, allowing further chemical transformations. These bulk scale oxidation processes usually employ molecular oxygen as the terminal oxidant as at this scale it is typically the only economically viable oxidant. The produced commodity chemicals possess limited functionality and usually show a high degree of symmetry thereby avoiding selectivity issues. In sharp contrast in the production of fine chemicals preference is still given to classical oxidants. Considering the strive for greener production processes the use of O2, the most abundant and greenest oxidant, is a logical choice. Given the rich functionality and complexity of fine chemicals achieving regio/chemoselectivity is a major challenge. This review presents an overview of the most important catalytic systems recently described for aerobic oxidation, and the current insight in their reaction mechanism.

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Section: Angewandte Chemiementioning

confidence: 99%

Catalytic Aerobic Oxidation of C(sp³)−H Bonds

2019

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“…The reaction was carried out in a 5 ml PFA capillary reactor at atmospheric pressure in 45 min residence time under 365 nm LED irradiation. The methodology was applied to the oxidation of terpenoid natural products, including the gram scale oxidation (1.5 h residence time, 10 ml reactor volume) of the sesquiterpene antimalarial, artemisinin [239]. Due to the electrophilic nature of the Scheme 73 Air oxidation of ethylbenzene to acetophenone or benzoic acid in flow catalyst, both methods allow the site-selective oxidation of a methylene group to a ketone [240,241].…”

Section: − O Bond Formationmentioning

confidence: 99%

Pushing the boundaries of C–H bond functionalization chemistry using flow technology

2020

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C-H functionalization chemistry is one of the most vibrant research areas within synthetic organic chemistry. While most researchers focus on the development of small-scale batch-type transformations, more recently such transformations have been carried out in flow reactors to explore new chemical space, to boost reactivity or to enable scalability of this important reaction class. Herein, an up-to-date overview of C-H bond functionalization reactions carried out in continuous-flow microreactors is presented. A comprehensive overview of reactions which establish the formal conversion of a C-H bond into carbon-carbon or carbonheteroatom bonds is provided; this includes metal-assisted C-H bond cleavages, hydrogen atom transfer reactions and C-H bond functionalizations which involve an S E-type process to aromatic or olefinic systems. Particular focus is devoted to showcase the advantages of flow processing to enhance C-H bond functionalization chemistry. Consequently, it is our hope that this review will serve as a guide to inspire researchers to push the boundaries of C-H functionalization chemistry using flow technology.

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“…Noël and his group are interested in the development of new catalytic strategies and technologies for chemical synthesis, and he was honored for his work on continuous photochemical conversion in microfluidic systems. He has reported in Angewandte Chemie on the visible‐light‐mediated arylation of cysteine in batch and flow, and on selective C(sp 3 )−H aerobic oxidation enabled by photocatalysis in flow …”

Section: Awarded …mentioning

confidence: 99%

Japan Prize: A. Yoshino / Merck–Banyu Lectureship: N. Kumagai / DECHEMA Prize: T. Noël

2018

Angew Chem Int Ed

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Selective C(sp³)−H Aerobic Oxidation Enabled by Decatungstate Photocatalysis in Flow

Cited by 194 publications

References 82 publications

Catalytic Aerobic Oxidation of C(sp³)−H Bonds

Catalytic Aerobic Oxidation of C(sp³)−H Bonds

Pushing the boundaries of C–H bond functionalization chemistry using flow technology

Japan Prize: A. Yoshino / Merck–Banyu Lectureship: N. Kumagai / DECHEMA Prize: T. Noël

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Selective C(sp3)−H Aerobic Oxidation Enabled by Decatungstate Photocatalysis in Flow

Cited by 194 publications

References 82 publications

Catalytic Aerobic Oxidation of C(sp3)−H Bonds

Catalytic Aerobic Oxidation of C(sp3)−H Bonds

Pushing the boundaries of C–H bond functionalization chemistry using flow technology

Japan Prize: A. Yoshino / Merck–Banyu Lectureship: N. Kumagai / DECHEMA Prize: T. Noël

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Selective C(sp³)−H Aerobic Oxidation Enabled by Decatungstate Photocatalysis in Flow

Catalytic Aerobic Oxidation of C(sp³)−H Bonds

Catalytic Aerobic Oxidation of C(sp³)−H Bonds