Department of Chemistry, Tufts University, 62 Talbot Ave., Medford, MA 02155, USA.
Chemistry. 2010 Dec 17;16(47):13995-4006. doi: 10.1002/chem.201002577.
Mechanism of substrate oxidations with hydrogen peroxide in the presence of a highly reactive, biomimetic, iron aminopyridine complex, [Fe(II)(bpmen)(CH(3)CN)(2)]ClO(4) (1; bpmen=N,N'-dimethyl-N,N'-bis(2-pyridylmethyl)ethane-1,2-diamine), is elucidated. Complex 1 has been shown to be an excellent catalyst for epoxidation and functional-group-directed aromatic hydroxylation using H(2)O(2), although its mechanism of action remains largely unknown. Efficient intermolecular hydroxylation of unfunctionalized benzene and substituted benzenes with H(2)O(2) in the presence of 1 is found in the present work. Detailed mechanistic studies of the formation of iron(III)-phenolate products are reported. We have identified, generated in high yield, and experimentally characterized the key Fe(III)(OOH) intermediate (λ(max)=560 nm, rhombic EPR signal with g=2.21, 2.14, 1.96) formed by 1 and H(2)O(2). Stopped-flow kinetic studies showed that Fe(III)(OOH) does not directly hydroxylate the aromatic rings, but undergoes rate-limiting self-decomposition producing transient reactive oxidant. The formation of the reactive species is facilitated by acid-assisted cleavage of the O-O bond in the iron-hydroperoxide intermediate. Acid-assisted benzene hydroxylation with 1 and a mechanistic probe, 2-Methyl-1-phenyl-2-propyl hydroperoxide (MPPH), correlates with O-O bond heterolysis. Independently generated Fe(IV)=O species, which may originate from O-O bond homolysis in Fe(III)(OOH), proved to be inactive toward aromatic substrates. The reactive oxidant derived from 1 exchanges its oxygen atom with water and electrophilically attacks the aromatic ring (giving rise to an inverse H/D kinetic isotope effect of 0.8). These results have revealed a detailed experimental mechanistic picture of the oxidation reactions catalyzed by 1, based on direct characterization of the intermediates and products, and kinetic analysis of the individual reaction steps. Our detailed understanding of the mechanism of this reaction revealed both similarities and differences between synthetic and enzymatic aromatic hydroxylation reactions.
阐明了在高反应性、仿生铁氨基吡啶配合物[Fe(II)(bpmen)(CH(3)CN)(2)]ClO(4)(1;bpmen=N,N'-二甲-N,N'-双(2-吡啶基甲基)乙二胺)存在下用过氧化氢进行底物氧化的机制。尽管其作用机制在很大程度上仍不清楚,但 1 已被证明是使用 H(2)O(2)进行环氧化和官能团定向芳族羟化的极好催化剂。本工作发现 1 存在时,H(2)O(2)可有效实现未官能化苯和取代苯的分子间羟化。报道了形成铁(III)-苯氧产物的详细机理研究。我们已经鉴定、高产率生成并通过实验表征了 1 和 H(2)O(2)形成的关键 Fe(III)(OOH)中间产物(λ(max)=560nm,菱形 EPR 信号,g=2.21、2.14、1.96)。停流动力学研究表明,Fe(III)(OOH)不会直接芳环羟化,而是经历限速的自分解产生瞬态反应性氧化剂。酸辅助铁过氧氢中间体 O-O 键断裂促进了活性物质的形成。酸辅助 1 和机理探针 2-甲基-1-苯基-2-丙基过氧化物(MPPH)与 O-O 键异裂的苯羟化反应相关。独立生成的 Fe(IV)=O 物种可能源于 Fe(III)(OOH)中的 O-O 键均裂,对芳基底物无活性。源于 1 的反应性氧化剂交换其氧原子与水并亲电攻击芳环(导致反 H/D 动力学同位素效应为 0.8)。这些结果基于中间产物和产物的直接表征以及各反应步骤的动力学分析,揭示了 1 催化的氧化反应的详细实验机理图。我们对该反应机制的详细理解揭示了合成和酶促芳族羟化反应之间的相似性和差异。
