利用变温质谱观察 Fe(V)=O 及其类似酶的 C-H 和 C=C 氧化反应。

Observation of Fe(V)=O using variable-temperature mass spectrometry and its enzyme-like C-H and C=C oxidation reactions.

机构信息

Departament de Química, Universitat de Girona, Campus de Montilivi, Girona 17071, Spain.

出版信息

Nat Chem. 2011 Sep 4;3(10):788-93. doi: 10.1038/nchem.1132.

PMID:21941251

Abstract

Oxo-transfer chemistry mediated by iron underpins many biological processes and today is emerging as synthetically very important for the catalytic oxidation of C-H and C=C moieties that are hard to activate conventionally. Despite the vast amount of research in this area, experimental characterization of the reactive species under catalytic conditions is very limited, although a Fe(V)=O moiety was postulated. Here we show, using variable-temperature mass spectrometry, the generation of a Fe(V)=O species within a synthetic non-haem complex at -40 °C and its reaction with an olefin. Also, with isotopic labelling we were able both to follow oxygen-atom transfer from H(2)O(2)/H(2)O through Fe(V)=O to the products and to probe the reactivity as a function of temperature. This study pioneers the implementation of variable-temperature mass spectrometry to investigate reactive intermediates.

摘要

铁介导的氧化转移化学是许多生物过程的基础，如今在催化氧化 C-H 和 C=C 键方面具有重要的合成意义，因为这些键通常很难被传统方法激活。尽管在该领域进行了大量研究，但在催化条件下对反应性物种的实验表征非常有限，尽管有人假设存在 Fe(V)=O 部分。在这里，我们使用变温质谱法，在 -40°C 下在合成的非血红素配合物中生成 Fe(V)=O 物种，并观察其与烯烃的反应。此外，通过同位素标记，我们既能够跟踪 H(2)O(2)/H(2)O 中的氧原子通过 Fe(V)=O 转移到产物中，又能够探测温度对反应性的影响。这项研究开创了使用变温质谱法研究反应性中间体的先河。

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利用变温质谱观察 Fe(V)=O 及其类似酶的 C-H 和 C=C 氧化反应。

Observation of Fe(V)=O using variable-temperature mass spectrometry and its enzyme-like C-H and C=C oxidation reactions.

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