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卟啉钴(III)“氮烯自由基”反应活性;从邻位YH取代基到钴结合芳基氮烯中间体氮烯部分的氢原子转移(Y = O,NH)

Porphyrin Cobalt(III) "Nitrene Radical" Reactivity; Hydrogen Atom Transfer from Ortho-YH Substituents to the Nitrene Moiety of Cobalt-Bound Aryl Nitrene Intermediates (Y = O, NH).

作者信息

Goswami Monalisa, Rebreyend Christophe, de Bruin Bas

机构信息

Van 't Hoff Institute for Molecular Sciences, University of Amsterdam, Science Park 904, 1098 XH Amsterdam, The Netherlands.

出版信息

Molecules. 2016 Feb 20;21(2):242. doi: 10.3390/molecules21020242.

DOI:10.3390/molecules21020242
PMID:26907236
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6274064/
Abstract

In the field of cobalt(II) porphyrin-catalyzed metallo-radical reactions, organic azides have emerged as successful nitrene transfer reagents. In the pursuit of employing ortho-YH substituted (Y = O, NH) aryl azides in Co(II) porphyrin-catalyzed nitrene transfer reactions, unexpected hydrogen atom transfer (HAT) from the OH or NH₂ group in the ortho-position to the nitrene moiety of the key radical-intermediate was observed. This leads to formation of reactive ortho-iminoquinonoid (Y = O) and phenylene diimine (Y = NH) species. These intermediates convert to subsequent products in non-catalyzed reactions, as is typical for these free organic compounds. As such, the observed reactions prevent the anticipated cobalt-mediated catalytic radical-type coupling of the nitrene radical intermediates to alkynes or alkenes. Nonetheless, the observed reactions provide valuable insights into the reactivity of transition metal nitrene-radical intermediates, and give access to ortho-iminoquinonoid and phenylene diimine intermediates from ortho-YH substituted aryl azides in a catalytic manner. The latter can be employed as intermediates in one-pot catalytic transformations. From the ortho-hydroxy aryl azide substrates both phenoxizinones and benzoxazines could be synthesized in high yields. From the ortho-amino aryl azide substrates azabenzene compounds were obtained as the main products. Computational studies support these observations, and reveal that HAT from the neighboring OH and NH₂ moiety to the nitrene radical moiety has a low energy barrier.

摘要

在钴(II)卟啉催化的金属自由基反应领域,有机叠氮化物已成为成功的氮烯转移试剂。在探索将邻位-YH取代(Y = O,NH)的芳基叠氮化物用于钴(II)卟啉催化的氮烯转移反应过程中,观察到了邻位的OH或NH₂基团向关键自由基中间体的氮烯部分发生意外的氢原子转移(HAT)。这导致形成了活性邻亚氨基醌类(Y = O)和亚苯基二亚胺类(Y = NH)物种。这些中间体在非催化反应中转化为后续产物,这是这些游离有机化合物的典型情况。因此,观察到的反应阻止了预期的钴介导的氮烯自由基中间体与炔烃或烯烃的催化自由基型偶联。尽管如此,观察到的反应为过渡金属氮烯自由基中间体的反应活性提供了有价值的见解,并以催化方式从邻位-YH取代的芳基叠氮化物获得了邻亚氨基醌类和亚苯基二亚胺类中间体。后者可作为一锅法催化转化的中间体。从邻羟基芳基叠氮化物底物可以高产率合成吩恶嗪酮和苯并恶嗪。从邻氨基芳基叠氮化物底物获得氮杂苯化合物作为主要产物。计算研究支持了这些观察结果,并表明从相邻的OH和NH₂部分向氮烯自由基部分的氢原子转移具有较低的能垒。

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