Mechanism of the Molybdenum-Mediated Cadogan Reaction

Marta Castiñeira Reis; Marta Marín-Luna; Carlos Silva López; Olalla Nieto Faza

doi:10.1021/acsomega.8b01278

Mechanism of the Molybdenum-Mediated Cadogan Reaction

Marta Castiñeira Reis, Marta Marín-Luna, Carlos Silva López^*, Olalla Nieto Faza

^*Corresponding author voor dit werk

Onderzoeksoutput › Academic › peer review

15 Citaten (Scopus)

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Oxygen atom transfer reactions are receiving increasing attention because they bring about paramount transformations in the current biomass processing industry. Significant efforts have therefore been made lately in the development of efficient and scalable methods to deoxygenate organic compounds. One recent alternative involves the modification of the Cadogan reaction in which a Mo(VI) core catalyzes the reduction of o-nitrostyrene derivatives to indoles in the presence of PPh₃. We have used density functional theory calculations to perform a comprehensive mechanistic study on this transformation, in which we find two clearly defined stages: an associative path from the nitro to the nitroso compound, characterized by the reduction of the catalyst in the first step, and a peculiar mechanism involving oxazaphosphiridine and nitrene intermediates leading to an indole product, where the metal catalyst does not participate.

Originele taal-2	English
Pagina's (van-tot)	7019-7026
Aantal pagina's	8
Tijdschrift	ACS Omega
Volume	3
Nummer van het tijdschrift	6
DOI's	https://doi.org/10.1021/acsomega.8b01278
Status	Published - 30-jun.-2018
Extern gepubliceerd	Ja

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AU - Silva López, Carlos

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Y1 - 2018/6/30

N2 - Oxygen atom transfer reactions are receiving increasing attention because they bring about paramount transformations in the current biomass processing industry. Significant efforts have therefore been made lately in the development of efficient and scalable methods to deoxygenate organic compounds. One recent alternative involves the modification of the Cadogan reaction in which a Mo(VI) core catalyzes the reduction of o-nitrostyrene derivatives to indoles in the presence of PPh3. We have used density functional theory calculations to perform a comprehensive mechanistic study on this transformation, in which we find two clearly defined stages: an associative path from the nitro to the nitroso compound, characterized by the reduction of the catalyst in the first step, and a peculiar mechanism involving oxazaphosphiridine and nitrene intermediates leading to an indole product, where the metal catalyst does not participate.

AB - Oxygen atom transfer reactions are receiving increasing attention because they bring about paramount transformations in the current biomass processing industry. Significant efforts have therefore been made lately in the development of efficient and scalable methods to deoxygenate organic compounds. One recent alternative involves the modification of the Cadogan reaction in which a Mo(VI) core catalyzes the reduction of o-nitrostyrene derivatives to indoles in the presence of PPh3. We have used density functional theory calculations to perform a comprehensive mechanistic study on this transformation, in which we find two clearly defined stages: an associative path from the nitro to the nitroso compound, characterized by the reduction of the catalyst in the first step, and a peculiar mechanism involving oxazaphosphiridine and nitrene intermediates leading to an indole product, where the metal catalyst does not participate.

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Mechanism of the Molybdenum-Mediated Cadogan Reaction

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