Visible-Light Mediated Oxidative Fragmentation of Ethers and Acetals by Means of Fe(III) Catalysis

Lindroth, Rickard; Ondrejková, Alica; Wallentin, Carl‐Johan

doi:10.1021/acs.orglett.2c00231

Cited by 14 publications

(12 citation statements)

References 36 publications

(74 reference statements)

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“…Observation of slow corrosion of the metallic needle, likely due to formation of HBr during the progression of the reaction, is consistent with this assumption. In our previous efforts, we have observed that ring-opening of cyclic ethers can be facilitated under similar conditions, in the presence of trace amount of transition metals, 26 which further supports the hypothesis of metal catalysis. Therefore, the metal composition of the needle was evaluated by XRF, and major metals present in the needle were tested in our system (see ESI †).…”

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confidence: 73%

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Utilizing a needle as a source of iron in synergistic dual photoredox catalytic generation of alkoxy radicals

et al. 2022

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confidence: 73%

“…This process is further facilitated by an iron catalyzed generation of both ˙CCl 3 and carbocation under blue-light irradiation. 26 Lastly, the ring-opening event of carbocation by bromide ion provides the final bromoketone.…”

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confidence: 99%

Utilizing a needle as a source of iron in synergistic dual photoredox catalytic generation of alkoxy radicals

et al. 2022

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“…We have recently in our laboratory disclosed an Fe-catalyzed oxidative fragmentation of ethers and acetals giving distally brominated ketones or esters, respectively (Scheme ). Similar to that in the ATRA reactions, the catalyst engages BrCCl 3 reductively, giving a trichloromethyl radical and a bromide ion after mesolytic cleavage. But contrary to an addition, the trichloromethyl radical abstracts a hydrogen from the substrate to generate an α-oxyradical.…”

Section: Resultsmentioning

confidence: 97%

“…For full exploration of the utility of the heterogenized catalyst, four reactions that constitute examples of both oxidative and reductive quenching mechanisms were selected. These include reductive dehalogenation, atom-transfer radical addition (ATRA), oxidative fragmentation of ethers and acetals, and aerobic oxidative hydroxylation of boronic acids (Figure ). Additionally, we also explored the olefin E -to- Z isomerization of cinnamates to evaluate the performance of an energy-transfer pathway from the excited triplet state of the catalyst, *PC(T 1 ), to generate the excited triplet state of the alkene …”

Section: Resultsmentioning

confidence: 99%

Sustainable Ir-Photoredox Catalysis by Means of Heterogenization

et al. 2022

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A heterogenized iridium catalyst was employed to perform photoredox catalysis for a collection of mechanistically orthogonal reactions using very low quantities of iridium (0.01–0.1 mol %). The heterogenized construct consists of an organometallic iridium coordination complex bonded to an aluminum metal oxide solid-state support via an anchoring group. The solid-state support allows for easy recovery and reusability of the catalyst. Evaluation of the catalytic activity was performed with five different reactions, showing broad applicability and demonstrating the general potential for a heterogenized strategy. Moreover, the heterogenized catalyst was shown to be reusable up to five times and also mediated the reactions with much higher efficiency than the original processes by employing the corresponding homogeneous catalyst. As a result of the low catalyst loadings employed, the feasibility of reusage, and faster reaction times, this catalyst offers a more sustainable option when precious metal catalysts are used in organic synthesis. Finally, the catalyst was successfully applied to a gram-scale reaction, showing it is susceptible to scalability.

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“…The active species can oxidize/reduce the substrates, generating the corresponding active radicals. Though some reports pointed out that these active species decayed back to their ground states extremely rapid, 7b oxidative/reductive quenching can still happen through initial propagation or other processes. For the majority of the intramolecular charge transfer modes (Scheme 1 C), ligand–metal charge transfer (LMCT) processes realize the desired homolysis of the metal–substrate bonds.…”

Section: Visible-light-induced Fe-catalyzed Reactionsmentioning

confidence: 99%

Visible-Light-Induced Iron Group Metal Catalysis: Recent Developments in Organic Synthesis

Yin¹,

Wang²,

Cai³

et al. 2022

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One central research goal of the modern organic chemistry society is to develop sustainable synthetic methodologies. Visible light-induced transformation applying earth-abundant metals as catalysts is a good reply to the concern. In this short review, recent developments of organic photocatalysis applying iron group metal (Fe, Co, Ni) catalysts are discussed. Reaction types, the catalyst details, and mechanisms are introduced.

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Visible-Light Mediated Oxidative Fragmentation of Ethers and Acetals by Means of Fe(III) Catalysis

Cited by 14 publications

References 36 publications

Utilizing a needle as a source of iron in synergistic dual photoredox catalytic generation of alkoxy radicals

Utilizing a needle as a source of iron in synergistic dual photoredox catalytic generation of alkoxy radicals

Sustainable Ir-Photoredox Catalysis by Means of Heterogenization

Visible-Light-Induced Iron Group Metal Catalysis: Recent Developments in Organic Synthesis

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