QBIS Research Group, Departament de Química, Universitat de Girona, Campus Montilivi, Girona E-17071, Catalonia, Spain.
J Org Chem. 2013 Feb 15;78(4):1421-33. doi: 10.1021/jo302196q. Epub 2013 Jan 28.
Selective oxidation of alkyl C-H groups constitutes one of the highest challenges in organic synthesis. In this work, we show that mononuclear iron coordination complexes Λ-[Fe(CF(3)SO(3))(2)((S,S,R)-MCPP)] (Λ-1P), Δ-[Fe(CF(3)SO(3))(2)((R,R,R)-MCPP)] (Δ-1P), Λ-[Fe(CF(3)SO(3))(2)((S,S,R)-BPBPP)] (Λ-2P), and Δ-[Fe(CF(3)SO(3))(2)((R,R,R)-BPBPP)] (Δ-2P) catalyze the fast, efficient, and selective oxidation of nonactivated alkyl C-H groups employing H(2)O(2) as terminal oxidant. These complexes are based on tetradentate N-based ligands and contain iron centers embedded in highly structured coordination sites defined by two bulky 4,5-pinenopyridine donor ligands, a chiral diamine ligand backbone, and chirality at the metal (Λ or Δ). X-ray diffraction analysis shows that in Λ-1P and Λ-2P the pinene rings create cavity-like structures that isolate the iron site. The efficiency and regioselectivity in catalytic C-H oxidation reactions of these structurally rich complexes has been compared with those of Λ-[Fe(CF(3)SO(3))(2)((S,S)-MCP)] (Λ-1), Λ-[Fe(CF(3)SO(3))(2)((S,S)-BPBP)] (Λ-2), Δ-[Fe(CF(3)SO(3))(2)((R,R)-BPBP)] (Δ-2), Λ-Fe(CH(3)CN)(2)((S,S)-BPBP)(2) (Λ-2SbF(6)), and Δ-Fe(CH(3)CN)(2)((R,R)-BPBP)(2) (Δ-2SbF(6)), which lack the steric bulk introduced by the pinene rings. Cavity-containing complexes Λ-1P and Λ-2P exhibit enhanced activity in comparison with Δ-1P, Δ-2P, Λ-1, Λ-2, and Λ-2SbF(6). The regioselectivity exhibited by catalysts Λ-1P, Λ-2P, Δ-1P, and Δ-2P in the C-H oxidation of simple organic molecules can be predicted on the basis of the innate properties of the distinct C-H groups of the substrate. However, in specific complex organic molecules where oxidation of multiple C-H sites is competitive, the highly elaborate structure of the catalysts allows modulation of C-H regioselectivity between the oxidation of tertiary and secondary C-H groups and also among multiple methylene sites, providing oxidation products in synthetically valuable yields. These selectivities complement those accomplished with structurally simpler oxidants, including non-heme iron catalysts Λ-2 and Λ-2SbF(6).
烷基 C-H 基团的选择性氧化是有机合成中最具挑战性的问题之一。在这项工作中,我们表明单核铁配合物 Λ-[Fe(CF(3)SO(3))(2)((S,S,R)-MCPP)] (Λ-1P)、Δ-[Fe(CF(3)SO(3))(2)((R,R,R)-MCPP)] (Δ-1P)、Λ-[Fe(CF(3)SO(3))(2)((S,S,R)-BPBPP)] (Λ-2P) 和 Δ-[Fe(CF(3)SO(3))(2)((R,R,R)-BPBPP)] (Δ-2P) 可以使用 H(2)O(2)作为末端氧化剂,快速、高效、选择性地氧化非活化的烷基 C-H 基团。这些配合物基于四齿 N 基配体,含有铁中心,嵌入由两个庞大的 4,5-皮诺吡啶供体配体、手性二胺配体骨架和金属 (Λ 或 Δ) 手性定义的高度结构化的配位位点。X 射线衍射分析表明,在 Λ-1P 和 Λ-2P 中,蒎烯环形成了隔离铁位的腔状结构。这些结构丰富的配合物在催化 C-H 氧化反应中的效率和区域选择性已与 Λ-[Fe(CF(3)SO(3))(2)((S,S)-MCP)] (Λ-1)、Λ-[Fe(CF(3)SO(3))(2)((S,S)-BPBP)] (Λ-2)、Δ-[Fe(CF(3)SO(3))(2)((R,R)-BPBP)] (Δ-2)、Λ-Fe(CH(3)CN)(2)((S,S)-BPBP)(2) (Λ-2SbF(6)) 和 Δ-Fe(CH(3)CN)(2)((R,R)-BPBP)(2) (Δ-2SbF(6)) 进行了比较,后者缺乏蒎烯环引入的空间位阻。与 Δ-1P、Δ-2P、Λ-1、Λ-2 和 Λ-2SbF(6)相比,具有腔的配合物 Λ-1P 和 Λ-2P 表现出更高的活性。催化剂 Λ-1P、Λ-2P、Δ-1P 和 Δ-2P 在简单有机分子 C-H 氧化中的区域选择性可以根据底物不同 C-H 基团的固有性质来预测。然而,在多个 C-H 位点竞争氧化的特定复杂有机分子中,催化剂的高度复杂结构允许调节 C-H 区域选择性,包括叔 C-H 和仲 C-H 基团之间的氧化以及多个亚甲基位点之间的氧化,以提供具有合成价值的氧化产物。这些选择性补充了那些使用结构更简单的氧化剂(包括非血红素铁催化剂 Λ-2 和 Λ-2SbF(6))所实现的选择性。
