Comparative Nitrene-Transfer Chemistry to Olefinic Substrates Mediated by a Library of Anionic Mn(II) Triphenylamido-Amine Reagents and M(II) Congeners (M = Fe, Co, Ni) Favoring Aromatic over Aliphatic Alkenes

Comparative Nitrene-Transfer Chemistry to Olefinic Substrates Mediated by a Library of Anionic Mn(II) Triphenylamido-Amine Reagents and M(II) Congeners (M = Fe, Co, Ni) Favoring Aromatic over Aliphatic Alkenes

Selective amination of sigma and pi entities such as C-H and C=C bonds of substrates remains a challenging endeavor for current catalytic methodologies devoted to the synthesis of abundant nitrogen-containing chemicals. The present work addresses an approach toward discriminating aromatic over aliphatic alkenes in aziridination reactions, relying on the use of anionic metal reagents (M = Mn, Fe, Co, Ni) to attenuate reactivity in a metal-dependent manner. A family of Mn-II reagents bearing a triphenylamido-amine scaffold and various pendant arms has been synthesized and characterized by various techniques, including cyclic voltammetry. Aziridination of styrene by PhI=NTs in the presence of each Mn-II catalyst establishes a trend of increasing yield with increasing Mn-II/III anodic potential. The Fe-II, Co-II, and Ni-II congeners of the highest-yielding Mn-II catalyst have been synthesized and explored in the aziridination of aromatic and aliphatic alkenes, exhibiting good to high yields with para-substituted styrenes, low to modest yields with sterically congested styrenes, and invariably low yields with aliphatic olefins. Co-II aziridination in comparison to Mn-II but is less selective than Mn-II in competitive aziridinations of nonconjugated olefins. Indeed, Mn-II proved to be highly selective even versus well-established copper and rhodium aziridination reagents. Mechanistic investigations and computational studies indicate that all metals follow a two-step styrene aziridination pathway (successive formation of two N-C bonds), featuring a turnover-limiting metal-nitrene addition to an olefinic carbon, followed by product-determining ring closure. Both steps exhibit activation barriers in the order Fe > Mn > Co, most likely stemming from relevant metal-nitrene electrophilicities and M-II/III redox potentials. The aziridination of aliphatic olefins follows the same stepwise path, albeit with a considerably higher activation barrier and a weaker driving force for the formation of the initial N-C bond, succeeded by ring closure with a miniscule barrier.

Vivek Bagchi Anshika Kalra Purak Das Patrina Paraskevopoulou Saidulu Gorla Lin Ai Qiuwen Wang Sudip Mohapatra Amitava Choudhury Zhicheng Sun Thomas R. Cundari Pericles Stavropoulos

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