Proton-triggered chemoselective halogenation of aliphatic C–H bonds with nonheme FeIV-oxo complexes

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Neus Pagès-Vilà , Ilaria Gamba , Martin Clémancey , Jean-Marc Latour , Anna Company , Miquel Costas
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Abstract

Halogenation of aliphatic C–H bonds is a chemical transformation performed in nature by mononuclear nonheme iron dependent halogenases. The mechanism involves the formation of an iron(IV)-oxo-chloride species that abstracts the hydrogen atom from the reactive C–H bond to form a carbon-centered radical that selectively reacts with the bound chloride ligand, a process commonly referred to as halide rebound. The factors that determine the halide rebound, as opposed to the reaction with the incipient hydroxide ligand, are not clearly understood and examples of well-defined iron(IV)-oxo-halide compounds competent in C–H halogenation are scarce. In this work we have studied the reactivity of three well-defined iron(IV)-oxo complexes containing variants of the tetradentate 1-(2-pyridylmethyl)-1,4,7-triazacyclononane ligand (Pytacn). Interestingly, these compounds exhibit a change in their chemoselectivity towards the functionalization of C–H bonds under certain conditions: their reaction towards C–H bonds in the presence of a halide anionleads to exclusive oxygenation, while the addition of a superacid results in halogenation. Almost quantitative halogenation of ethylbenzene is observed when using the two systems with more sterically congested ligands and even the chlorination of strong C–H bonds such as those of cyclohexane is performed when a methyl group is present in the sixth position of the pyridine ring of the ligand. Mechanistic studies suggest that both reactions, oxygenation and halogenation, proceed through a common rate determining hydrogen atom transfer step and the presence of the acid dictates the fate of the resulting alkyl radical towards preferential halogenation over oxygenation.

Abstract Image

非血红素 FeIV-oxo 复合物对脂肪族 C-H 键的质子触发化学选择性卤化作用。
脂肪族 C-H 键的卤化是单核非血红素铁依赖卤化酶在自然界中进行的一种化学变化。其机理包括形成铁(IV)-氧-氯物种,从反应性 C-H 键中抽取氢原子,形成碳中心自由基,选择性地与结合的氯配体发生反应,这一过程通常称为卤化物反弹。目前还不清楚决定卤化物反弹(而不是与初生的氢氧配体反应)的因素,也很少有定义明确的铁(IV)-氧-卤化合物能够进行 C-H 卤化反应。在这项工作中,我们研究了含有四价 1-(2-吡啶基甲基)-1,4,7-三氮杂环壬烷配体(Pytacn)变体的三种定义明确的铁(IV)-氧代配合物的反应性。有趣的是,这些化合物在特定条件下对 C-H 键官能化的化学选择性发生了变化:在卤化物阴离子存在下,它们对 C-H 键的反应完全是氧化,而加入超酸后则是卤化。当这两种体系中的配体立体拥挤程度较高时,几乎可以观察到乙苯的定量卤化反应;而当配体吡啶环的第六个位置存在甲基时,甚至可以观察到强 C-H 键(如环己烷的 C-H 键)的氯化反应。机理研究表明,氧合和卤化这两种反应都是通过一个共同的决定速率的氢原子转移步骤进行的,酸的存在决定了生成的烷基自由基的命运,即优先卤化而不是氧合。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
7.20
自引率
4.30%
发文量
567
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