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隐蔽自由基:三苯甲基、二苯甲酮和苯乙炔的铁配合物

Masked Radicals: Iron Complexes of Trityl, Benzophenone, and Phenylacetylene.

作者信息

MacLeod K Cory, DiMucci Ida M, Zovinka Edward P, McWilliams Sean F, Mercado Brandon Q, Lancaster Kyle M, Holland Patrick L

机构信息

Department of Chemistry, Yale University, 225 Prospect Street, New Haven, Connecticut 06511.

Department of Chemistry and Chemical Biology, Cornell University, Ithaca New York 14853.

出版信息

Organometallics. 2019 Nov 11;38(21):4224-4232. doi: 10.1021/acs.organomet.9b00534. Epub 2019 Oct 10.

DOI:10.1021/acs.organomet.9b00534
PMID:34103782
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8184022/
Abstract

We report the first Fe─CPh complex, and show that the long Fe─C bond can be disrupted by neutral π-acceptor ligands (benzophenone and phenylacetylene) to release the triphenylmethyl radical. The products are formally iron(I) complexes, but X-ray absorption spectroscopy coupled with density functional and multireference calculations indicates that the best description of all the complexes is iron(II). In the formally iron(I) complexes, this does not imply that the π-acceptor ligand has radical character, because the iron(II) description arises from doubly-occupied frontier molecular orbitals that are shared equitably by the iron and the π-acceptor ligand, and the unpaired electrons lie on the metal. Despite the lack of substantial radical character on the ligands, alkyne and ketone fragments can couple to form a high-spin iron(III) complex with a cyclized metalladihydrofuran core.

摘要

我们报道了首个铁-三苯基甲基配合物,并表明长的铁-碳键可被中性π-受体配体(二苯甲酮和苯乙炔)破坏,从而释放出三苯甲基自由基。产物形式上是铁(I)配合物,但X射线吸收光谱结合密度泛函和多参考计算表明,所有配合物的最佳描述是铁(II)。在形式上为铁(I)的配合物中,这并不意味着π-受体配体具有自由基特征,因为铁(II)的描述源于由铁和π-受体配体公平共享的双占据前沿分子轨道,且未成对电子位于金属上。尽管配体上缺乏显著的自由基特征,但炔烃和酮片段可偶联形成具有环化金属二氢呋喃核心的高自旋铁(III)配合物。

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