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环戊二烯基铑(III)配合物中顺序性环甲基C-H活化的动力学和机理

Kinetics and mechanism of sequential ring methyl C-H activation in cyclopentadienyl rhodium(III) complexes.

作者信息

Sink Alexandra, Banerjee Samya, Wolny Juliusz A, Imberti Cinzia, Lant Edward C, Walker Marc, Schünemann Volker, Sadler Peter J

机构信息

Department of Chemistry, University of Warwick, Gibbet Hill Road, Coventry CV4 7AL, UK.

Department of Chemistry, Indian Institute of Technology (BHU), Varanasi, UP-221005, India.

出版信息

Dalton Trans. 2022 Nov 1;51(42):16070-16081. doi: 10.1039/d2dt02079c.

DOI:10.1039/d2dt02079c
PMID:36043856
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9623609/
Abstract

We have studied activation of the methyl C-H bonds in the cyclopentadienyl ligands of half-sandwich Rh(III) complexes [-CpRh(N,N')Cl] by observing the dependence of sequential H/D exchange on variations in Cp = Cp* (complexes 1 and 2), MePhCp (Cp, 3) or MePhPhCp (Cp, 4), and chelated ligand ,' (bpy, 1; phen, 2-4). H/D exchange was fastest in d-MeOD ( = 10 min, 37 °C, complex 1), no H/D exchange was observed in DMSO/DO, and d-MeOD enhanced the rate in CDCN. The proposed Rh(I)-fulvene intermediate was trapped by [4 + 2] Diels-Alder reactions with conjugated dienes and characterized. The Rh(I) oxidation state was confirmed by X-ray photoelectron spectroscopy (XPS). Influence of solvent on the mechanisms of activation and Diels-Alder adduct formation was modelled using DFT calculations with the CAM-B3LYP functional and CEP-31 g basis set, and influence on the reaction profile of the dimiine ligand and phenyl substituent using the larger qzvp basis set. The Rh(III)-OH intemediate is stabilised by H-bonding with methanol and a Cp* CH hydrogen. The Rh(I)(Mefulvene) species, stabilised by interaction of methanol with a coordinated water, again by two H-bonds HO-HOMe (1.49 Å) and fulvene CH (1.94 Å), arises from synchronous transfer of the methanol OH proton to a Rh(III)-OH ligand and Cp* methyl hydrogen to the methanol oxygen. Additionally, the observed trend in catalytic activity for complexes 1-4 was reproduced by DFT calculations. These complexes form a novel class of catalytic molecular motors with a tunable rate of operation that can be stalled in a given state. They provide a basis for elucidation of the effects of ligand design on the contributions of electronic, rotational and vibrational energies to each step in the reaction pathway at the atomic level, consideration of which will enhance the design principles for the next generation of molecular machines.

摘要

我们通过观察连续的H/D交换对环戊二烯基(Cp)变化的依赖性,研究了半夹心型Rh(III)配合物[-CpRh(N,N')Cl]中环戊二烯基配体上甲基C-H键的活化情况。其中,Cp分别为Cp*(配合物1和2)、MePhCp(Cp,3)或MePhPhCp(Cp,4),以及螯合配体'(bpy,1;phen,2 - 4)。在d-MeOD中H/D交换最快(t1/2 = 10分钟,37°C,配合物1),在DMSO/DO中未观察到H/D交换现象,而d-MeOD能提高在CDCN中的反应速率。所提出的Rh(I)-富烯中间体通过与共轭二烯的[4 + 2]狄尔斯-阿尔德反应被捕获并进行了表征。Rh(I)氧化态通过X射线光电子能谱(XPS)得以确认。使用CAM - B3LYP泛函和CEP - 31g基组的密度泛函理论(DFT)计算对溶剂对活化机制和狄尔斯-阿尔德加合物形成的影响进行了模拟,使用更大的qzvp基组对二亚胺配体和苯基取代基对反应轮廓的影响进行了模拟。Rh(III)-OH中间体通过与甲醇以及Cp* CH氢形成氢键而得以稳定。Rh(I)(甲富烯)物种通过甲醇与配位水的相互作用再次通过两个氢键HO - HOMe(1.49 Å)和富烯CH(1.94 Å)得以稳定,它是由甲醇OH质子同步转移至Rh(III)-OH配体以及Cp*甲基氢转移至甲醇氧而产生的。此外,配合物1 - 4催化活性的观测趋势通过DFT计算得以重现。这些配合物构成了一类新型的催化分子马达,其运行速率可调且可在给定状态下停滞。它们为在原子水平阐明配体设计对反应路径中每一步电子、旋转和振动能量贡献的影响提供了基础,考虑这些因素将增强下一代分子机器的设计原则。

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