Photocatalyzed Annulation‐Biselenylation of Enynone with Diarylselenides toward Biselenium‐Substituted 1‐Indanones under Metal‐ and Photosensitizer‐Free Conditions DOI
Hang‐Dong Zuo,

Huafeng Yan,

Yuting Wang

и другие.

Chinese Journal of Chemistry, Год журнала: 2025, Номер unknown

Опубликована: Апрель 17, 2025

Comprehensive Summary A practical photocatalytic annulation‐biselenylation strategy has been developed for the efficient synthesis of biselenium‐substituted 1‐indanones (38 examples in total) with generally good yields (up to 95%) and excellent stereoselectivity (>19 : 1 Z / E ratio) by employing enynones diaryl selenides as starting materials under photosensitizer‐free conditions. The reaction mechanism involves a cascade process comprising homolytic cleavage, radical addition, 5‐ exo ‐ dig cyclization, capture, enabling sequential formation multiple bonds, such C(sp 3 )‐Se, )‐C(sp 2 ), )‐Se rapidly construct molecular complexity. Notably, this approach demonstrates wide substrate compatibility tolerability towards various functional groups. It is further characterized its remarkable efficiency creating chemical bonds achieving high atomic utilization 100%.

Язык: Английский

Photocatalyzed Annulation‐Biselenylation of Enynone with Diarylselenides toward Biselenium‐Substituted 1‐Indanones under Metal‐ and Photosensitizer‐Free Conditions DOI
Hang‐Dong Zuo,

Huafeng Yan,

Yuting Wang

и другие.

Chinese Journal of Chemistry, Год журнала: 2025, Номер unknown

Опубликована: Апрель 17, 2025

Comprehensive Summary A practical photocatalytic annulation‐biselenylation strategy has been developed for the efficient synthesis of biselenium‐substituted 1‐indanones (38 examples in total) with generally good yields (up to 95%) and excellent stereoselectivity (>19 : 1 Z / E ratio) by employing enynones diaryl selenides as starting materials under photosensitizer‐free conditions. The reaction mechanism involves a cascade process comprising homolytic cleavage, radical addition, 5‐ exo ‐ dig cyclization, capture, enabling sequential formation multiple bonds, such C(sp 3 )‐Se, )‐C(sp 2 ), )‐Se rapidly construct molecular complexity. Notably, this approach demonstrates wide substrate compatibility tolerability towards various functional groups. It is further characterized its remarkable efficiency creating chemical bonds achieving high atomic utilization 100%.

Язык: Английский

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