Martín Marta, Sola Eduardo, Tejero Santiago, Andrés José L, Oro Luis A
Departamento de Compuestos de Coordinación y Catálisis Homogénea, Instituto de Ciencia de Materiales de Aragón, Universidad de Zaragoza-CSIC and Instituto Universitario de Catálisis Homogénea, Universidad de Zaragoza, 50009 Zaragoza, Spain.
Chemistry. 2006 May 15;12(15):4043-56. doi: 10.1002/chem.200501230.
Complexes [IrH2(eta6-C6H6)(PiPr3)]BF4 (1) and [IrH2(NCMe)3(PiPr3)]BF4 (2) are catalyst precursors for homogeneous hydrogenation of N-benzylideneaniline under mild conditions. Precursor 1 generates the resting state [IrH2{eta5-(C6H5)NHCH2Ph}(PiPr3)]BF4 (3), while 2 gives rise to a mixture of [IrH{PhN=CH(C6H4)-kappaN,C}(NCMe)2(PiPr3)]BF4 (4) and [IrH{PhN=CH(C6H4)-kappaN,C}(NCMe)(NH2Ph)(PiPr3)]BF4 (5), in which the aniline ligand is derived from hydrolysis of the imine. The less hindered benzophenone imine forms the catalytically inactive, doubly cyclometalated compound [Ir{HN=CPh(C6H4)-kappaN,C}2(NH2CHPh2)(PiPr3)]BF4 (6). Hydrogenations with precursor 1 are fast and their reaction profiles are strongly dependent on solvent, concentrations, and temperature. Significant induction periods, minimized by addition of the amine hydrogenation product, are commonly observed. The catalytic rate law (THF) is rate = k[1][PhN=CHPh]p(H2). The results of selected stoichiometric reactions of potential catalytic intermediates exclude participation of the cyclometalated compounds [IrH{PhN=CH(C6H4)-kappaN,C}(S)2(PiPr3)]BF4 [S = acetonitrile (4), [D6]acetone (7), [D4]methanol (8)] in catalysis. Reactions between resting state 3 and D2 reveal a selective sequence of deuterium incorporation into the complex which is accelerated by the amine product. Hydrogen bonding among the components of the catalytic reaction was examined by MP2 calculations on model compounds. The calculations allow formulation of an ionic, outer-sphere, bifunctional hydrogenation mechanism comprising 1) amine-assisted oxidative addition of H2 to 3, the result of which is equivalent to heterolytic splitting of dihydrogen, 2) replacement of a hydrogen-bonded amine by imine, and 3) simultaneous H delta+/H delta- transfer to the imine substrate from the NH moiety of an arene-coordinated amine ligand and the metal, respectively.
配合物[IrH₂(η⁶-C₆H₆)(PiPr₃)]BF₄ (1)和[IrH₂(NCMe)₃(PiPr₃)]BF₄ (2)是在温和条件下用于N-亚苄基苯胺均相氢化的催化剂前体。前体1生成静止态[IrH₂{η⁵-(C₆H₅)NHCH₂Ph}(PiPr₃)]BF₄ (3),而2产生[IrH{PhN=CH(C₆H₄)-κN,C}(NCMe)₂(PiPr₃)]BF₄ (4)和[IrH{PhN=CH(C₆H₄)-κN,C}(NCMe)(NH₂Ph)(PiPr₃)]BF₄ (5)的混合物,其中苯胺配体源自亚胺的水解。位阻较小的二苯甲酮亚胺形成催化无活性的双环金属化化合物[Ir{HN=CPh(C₆H₄)-κN,C}₂(NH₂CHPh₂)(PiPr₃)]BF₄ (6)。用前体1进行的氢化反应很快,其反应过程强烈依赖于溶剂、浓度和温度。通常观察到显著的诱导期,通过添加胺氢化产物可使其最小化。催化速率定律(THF)为速率 = k[1][PhN=CHPh]p(H₂)。潜在催化中间体的选定化学计量反应结果排除了环金属化化合物[IrH{PhN=CH(C₆H₄)-κN,C}(S)₂(PiPr₃)]BF₄ [S = 乙腈(4)、[D₆]丙酮(7)、[D₄]甲醇(8)]参与催化。静止态3与D₂之间的反应揭示了氘选择性掺入配合物的序列,该序列被胺产物加速。通过对模型化合物进行MP2计算研究了催化反应各组分之间的氢键。这些计算使得能够构建一种离子型、外层球双功能氢化机理,该机理包括:1) 胺辅助的H₂对3的氧化加成,其结果等同于氢分子的异裂;2) 亚胺取代氢键合的胺;3) 分别从芳烃配位胺配体的NH部分和金属向亚胺底物同时进行Hδ⁺/Hδ⁻转移。
