QBIS Group, Departament de Química, Universitat de Girona, Campus de Montilivi, 17071 Girona, Catalonia, Spain.
Chemistry. 2012 Feb 13;18(7):2113-22. doi: 10.1002/chem.201102372. Epub 2012 Jan 16.
Reactions of the unsymmetric dicopper(II) peroxide complex Cu(II)(2)(μ-η(1):η(1)-O(2))(m-XYL(N3N4)) (1 O(2), where m-XYL is a heptadentate N-based ligand), with phenolates and phenols are described. Complex 1 O(2) reacts with p-X-PhONa (X = MeO, Cl, H, or Me) at -90 °C performing tyrosinase-like ortho-hydroxylation of the aromatic ring to afford the corresponding catechol products. Mechanistic studies demonstrate that reactions occur through initial reversible formation of metastable association complexes Cu(II)(2)(μ-η(1):η(1)-O(2))(p-X-PhO)(m-XYL(N3N4)) (1 O(2)⋅X-PhO) that then undergo ortho-hydroxylation of the aromatic ring by the peroxide moiety. Complex 1 O(2) also reacts with 4-X-substituted phenols p-X-PhOH (X = MeO, Me, F, H, or Cl) and with 2,4-di-tert-butylphenol at -90 °C causing rapid decay of 1 O(2) and affording biphenol coupling products, which is indicative that reactions occur through formation of phenoxyl radicals that then undergo radical C-C coupling. Spectroscopic UV/Vis monitoring and kinetic analysis show that reactions take place through reversible formation of ground-state association complexes Cu(II)(2)(μ-η(1):η(1)-O(2))(X-PhOH)(m-XYL(N3N4)) (1 O(2)⋅X-PhOH) that then evolve through an irreversible rate-determining step. Mechanistic studies indicate that 1 O(2) reacts with phenols through initial phenol binding to the Cu(2)O(2) core, followed by a proton-coupled electron transfer (PCET) at the rate-determining step. Results disclosed in this work provide experimental evidence that the unsymmetric 1 O(2) complex can mediate electrophilic arene hydroxylation and PCET reactions commonly associated with electrophilic Cu(2)O(2) cores, and strongly suggest that the ability to form substrate⋅Cu(2)O(2) association complexes may provide paths to overcome the inherent reactivity of the O(2)-binding mode. This work provides experimental evidence that the presence of a H(+) completely determines the fate of the association complex Cu(II)(2)(μ-η(1):η(1)-O(2))(X-PhO(H))(m-XYL(N3N4)) between a PCET and an arene hydroxylation reaction, and may provide clues to help understand enzymatic reactions at dicopper sites.
反应的非对称二铜(ii)过氧化物配合物[铜(ii)(2)(μ-η(1):η(1)-o(2))(m-xyl(n3n4))](2+)(1o(2),其中 m-xyl 是一种七齿配位 n 基配体),与酚盐和酚类。配合物 1o(2)与 p-x-phona(x = meo、cl、h 或 me)在-90°C 下反应,对芳环进行酪氨酸酶样邻位羟化,得到相应的儿茶酚产物。机理研究表明,反应通过初始可逆形成亚稳的缔合配合物[铜(ii)(2)(μ-η(1):η(1)-o(2))(p-x-pho)(m-xyl(n3n4))](+)(1o(2)·x-pho)进行,然后通过过氧化物部分对芳环进行邻位羟化。配合物 1o(2)还与 4-x-取代的酚 p-x-phoh(x = meo、me、f、h 或 cl)和 2,4-二叔丁基酚在-90°C 下反应,导致 1o(2)快速衰减,并生成联苯酚偶联产物,这表明反应通过形成酚氧自由基进行,然后自由基 c-c 偶联。光谱紫外/可见监测和动力学分析表明,反应通过形成基态缔合配合物[铜(ii)(2)(μ-η(1):η(1)-o(2))(x-phoh)(m-xyl(n3n4))](2+)(1o(2)·x-phoh)的可逆形成进行,然后通过不可逆的速率决定步骤进行演变。机理研究表明,1o(2)与酚类通过酚类与 cu(2)o(2)核的初始结合,然后在速率决定步骤进行质子偶联电子转移(pcet)进行反应。本工作提供的实验证据表明,非对称 1o(2)配合物可以介导亲电芳环羟化和 pcet 反应,这些反应通常与亲电 cu(2)o(2)核有关,并强烈表明形成底物-cu(2)o(2)缔合配合物的能力可能为克服 o(2)结合模式的固有反应性提供途径。本工作提供了实验证据表明,h(+)的存在完全决定了 pcet 和芳环羟化反应之间的缔合配合物[铜(ii)(2)(μ-η(1):η(1)-o(2))(x-pho(h))(m-xyl(n3n4))](n+)的命运,并可能为帮助理解二铜位点的酶反应提供线索。
