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解析具有百万倍反应活性的开放核双铁[HO-Fe-O-Fe═O]物种对C-H键活化的反应起源:自旋态、自旋耦合和自旋协同作用的作用

Deciphering the origin of million-fold reactivity observed for the open core diiron [HO-Fe-O-Fe[double bond, length as m-dash]O] species towards C-H bond activation: role of spin-states, spin-coupling, and spin-cooperation.

作者信息

Ansari Mursaleem, Senthilnathan Dhurairajan, Rajaraman Gopalan

机构信息

Department of Chemistry , Indian Institute of Technology Bombay , Mumbai 400076 , India . Email:

Center for Computational Chemistry , CRD , PRIST University , Vallam , Thanjavur , Tamilnadu 613403 , India.

出版信息

Chem Sci. 2020 Jun 18;11(39):10669-10687. doi: 10.1039/d0sc02624g. eCollection 2020 Oct 21.

DOI:10.1039/d0sc02624g
PMID:33209248
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7654192/
Abstract

High-valent metal-oxo species have been characterised as key intermediates in both heme and non-heme enzymes that are found to perform efficient aliphatic hydroxylation, epoxidation, halogenation, and dehydrogenation reactions. Several biomimetic model complexes have been synthesised over the years to mimic both the structure and function of metalloenzymes. The diamond-core [Fe(μ-O)] is one of the celebrated models in this context as this has been proposed as the catalytically active species in soluble methane monooxygenase enzymes (sMMO), which perform the challenging chemical conversion of methane to methanol at ease. In this context, a report of open core [HO(L)Fe-O-Fe(O)(L)] () gains attention as this activates C-H bonds a million-fold faster compared to the diamond-core structure and has the dual catalytic ability to perform hydroxylation as well as desaturation with organic substrates. In this study, we have employed density functional methods to probe the origin of the very high reactivity observed for this complex and also to shed light on how this complex performs efficient hydroxylation and desaturation of alkanes. By modelling fifteen possible spin-states for that could potentially participate in the reaction mechanism, our calculations reveal a doublet ground state for arising from antiferromagnetic coupling between the quartet Fe centre and the sextet Fe centre, which regulates the reactivity of this species. The unusual stabilisation of the high-spin ground state for Fe[double bond, length as m-dash]O is due to the strong overlap of with the orbital, reducing the antibonding interactions spin-cooperation. The electronic structure features computed for are consistent with experiments offering confidence in the methodology chosen. Further, we have probed various mechanistic pathways for the C-H bond activation as well as -OH rebound/desaturation of alkanes. An extremely small barrier height computed for the first hydrogen atom abstraction by the terminal Fe[double bond, length as m-dash]O unit was found to be responsible for the million-fold activation observed in the experiments. The barrier height computed for -OH rebound by the Fe-OH unit is also smaller suggesting a facile hydroxylation of organic substrates by . A strong spin-cooperation between the two iron centres also reduces the barrier for second hydrogen atom abstraction, thus making the desaturation pathway competitive. Both the spin-state as well as spin-coupling between the two metal centres play a crucial role in dictating the reactivity for species . By exploring various mechanistic pathways, our study unveils the fact that the bridged μ-oxo group is a poor electrophile for both C-H activation as well for -OH rebound. As more and more evidence is gathered in recent years for the open core geometry of sMMO enzymes, the idea of enhancing the reactivity an open-core motif has far-reaching consequences.

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/7632/7654192/b5f5855bd99f/d0sc02624g-f11.jpg
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摘要

高价金属氧物种已被表征为血红素酶和非血红素酶中的关键中间体,这些酶能高效地进行脂肪族羟基化、环氧化、卤化和脱氢反应。多年来已合成了几种仿生模型配合物,以模拟金属酶的结构和功能。在这种情况下,金刚石核[Fe(μ-O)]是著名的模型之一,因为它被认为是可溶性甲烷单加氧酶(sMMO)中的催化活性物种,该酶能轻松地将甲烷进行具有挑战性的化学转化为甲醇。在这种背景下,一篇关于开放核[HO(L)Fe-O-Fe(O)(L)]()的报道引起了关注,因为与金刚石核结构相比,它激活C-H键的速度快一百万倍,并且具有对有机底物进行羟基化以及去饱和的双重催化能力。在本研究中,我们采用密度泛函方法来探究该配合物所观察到的极高反应活性的起源,并阐明该配合物如何对烷烃进行高效的羟基化和去饱和反应。通过对可能参与反应机理的十五种可能的自旋态进行建模,我们的计算揭示了由于四重态铁中心和六重态铁中心之间的反铁磁耦合而产生的双重基态,这调节了该物种的反应活性。Fe[双键,长度为中虚线]O的高自旋基态的异常稳定是由于与轨道的强烈重叠,减少了反键相互作用 自旋协同作用。为计算得到的电子结构特征与实验结果一致,这为所选择的方法提供了信心。此外,我们探究了C-H键活化以及烷烃的-OH回弹/去饱和的各种机理途径。发现末端Fe[双键,长度为中虚线]O单元对第一个氢原子提取计算得到的势垒高度极小,这是实验中观察到的百万倍活化的原因。Fe-OH单元对-OH回弹计算得到的势垒高度也较小,这表明能对有机底物进行容易的羟基化反应。两个铁中心之间强烈的自旋协同作用也降低了第二个氢原子提取的势垒,从而使去饱和途径具有竞争力。两个金属中心之间的自旋态以及自旋耦合在决定物种的反应活性方面都起着关键作用。通过探索各种机理途径,我们的研究揭示了桥连的μ-氧基团对于C-H活化以及-OH回弹都是不良亲电试剂这一事实。近年来,随着越来越多关于sMMO酶开放核几何结构的证据被收集,通过开放核基序提高反应活性的想法具有深远的影响。

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