Department of Bioinspired Science, Center for Biomimetic Systems, Ewha Womans University, Seoul 120-750, Korea.
J Am Chem Soc. 2010 Dec 1;132(47):16977-86. doi: 10.1021/ja107177m. Epub 2010 Nov 9.
Metal-dioxygen adducts are key intermediates detected in the catalytic cycles of dioxygen activation by metalloenzymes and biomimetic compounds. In this study, mononuclear cobalt(III)-peroxo complexes bearing tetraazamacrocyclic ligands, Co(12-TMC)(O(2)) and Co(13-TMC)(O(2)), were synthesized by reacting Co(12-TMC)(CH(3)CN) and Co(13-TMC)(CH(3)CN), respectively, with H(2)O(2) in the presence of triethylamine. The mononuclear cobalt(III)-peroxo intermediates were isolated and characterized by various spectroscopic techniques and X-ray crystallography, and the structural and spectroscopic characterization demonstrated unambiguously that the peroxo ligand is bound in a side-on η(2) fashion. The O-O bond stretching frequency of Co(12-TMC)(O(2)) and Co(13-TMC)(O(2)) was determined to be 902 cm(-1) by resonance Raman spectroscopy. The structural properties of the CoO(2) core in both complexes are nearly identical; the O-O bond distances of Co(12-TMC)(O(2)) and Co(13-TMC)(O(2)) were 1.4389(17) Å and 1.438(6) Å, respectively. The cobalt(III)-peroxo complexes showed reactivities in the oxidation of aldehydes and O(2)-transfer reactions. In the aldehyde oxidation reactions, the nucleophilic reactivity of the cobalt-peroxo complexes was significantly dependent on the ring size of the macrocyclic ligands, with the reactivity of Co(13-TMC)(O(2)) > Co(12-TMC)(O(2)). In the O(2)-transfer reactions, the cobalt(III)-peroxo complexes transferred the bound peroxo group to a manganese(II) complex, affording the corresponding cobalt(II) and manganese(III)-peroxo complexes. The reactivity of the cobalt-peroxo complexes in O(2)-transfer was also significantly dependent on the ring size of tetraazamacrocycles, and the reactivity order in the O(2)-transfer reactions was the same as that observed in the aldehyde oxidation reactions.
金属-双氧加合物是金属酶和仿生化合物中检测到的双氧激活催化循环的关键中间体。在这项研究中,通过分别将[Co(12-TMC)(CH3CN)]2+和[Co(13-TMC)(CH3CN)]2+与 H2O2 在三乙胺存在下反应,合成了单核钴(III)-过氧配合物,它们分别带有四氮大环配体[Co(12-TMC)(O2)]+和[Co(13-TMC)(O2)]+。单核钴(III)-过氧中间体通过各种光谱技术和 X 射线晶体学进行了分离和表征,结构和光谱表征明确表明过氧配体以侧接 η2 方式结合。通过共振拉曼光谱确定[Co(12-TMC)(O2)]+和[Co(13-TMC)(O2)]+的过氧配体 O-O 键伸缩频率为 902 cm-1。两个配合物中 CoO2 核的结构性质几乎相同;[Co(12-TMC)(O2)]+和[Co(13-TMC)(O2)]+的 O-O 键距离分别为 1.4389(17) Å 和 1.438(6) Å。钴(III)-过氧配合物在醛的氧化和 O2-转移反应中表现出反应活性。在醛氧化反应中,钴-过氧配合物的亲核反应性显著依赖于大环配体的环大小,[Co(13-TMC)(O2)]+>[Co(12-TMC)(O2)]+。在 O2-转移反应中,钴(III)-过氧配合物将结合的过氧基团转移到锰(II)配合物上,得到相应的钴(II)和锰(III)-过氧配合物。钴-过氧配合物在 O2-转移中的反应性也显著依赖于四氮大环的环大小,并且在 O2-转移反应中的反应性顺序与醛氧化反应中观察到的相同。
