Castillo-Orellana Carlos, Vöhringer-Martinez Esteban, Villegas-Escobar Nery
Departamento de Físico-Química, Facultad de Ciencias Químicas, Universidad de Concepción, Concepción, 4070139, Chile.
J Mol Model. 2024 Oct 4;30(11):365. doi: 10.1007/s00894-024-06150-5.
The CO activation by low-valent group 14 catalysts encompasses the rupture of varied covalent bonds in a single transition state through a concerted pathway. The bond between the central main group atom and the hydride in the complex is elongated to trigger the formation of the C-H bond with CO accompanied by the concomitant formation of the E-O bond between the complex and CO to lead the corresponding formate product. Prior studies have established that besides the apolar nature of CO , its initial interaction with the complex is primarily governed by electrostatic interactions. Notably, other stabilizing interactions and the transfer of charge between catalysts and CO during the initial phases of the reaction have been ignored. In this study, we have quantified the non-covalent interactions and charge transfer that facilitate the activation of CO by group 14 main group complex. Our findings indicate that electrostatic interactions predominantly stabilize the complex and CO in the reactant region. However, induction energy becomes the main stabilizing force as the reaction progresses towards the transition state, surpassing electrostatics. Induction contributes about 50% to the stabilization at the transition state, followed by electrostatics (40%) and dispersion interactions (10%). Atomic charges calculated with the minimal basis iterative stockholder (MBIS) method reveal larger charge transfer for the back-side reaction path in which CO approaches the catalysts in contrast to the front-side approach. Notably, it was discovered that a minor initial bending of CO to approximately initiates the charge transfer process for all systems. Furthermore, our investigation of group 14 elements demonstrates a systematic reduction in both activation energies and charge transfer to CO while descending in group 14.
All studied reactions were characterized along the reaction coordinate obtained with the intrinsic reaction coordinate (IRC) methodology at the M06-2X/6-31 g(d,p) level of theory. Gibbs free energy in toluene was computed using electronic energies at the DLPNO-CCSD(T)/cc-pVTZ-SSD(E) level of theory. Vibrational and translational entropy corrections were applied to provide a more accurate description of the obtained Gibbs free energies. To better characterize the changes in the reaction coordinate for all reactions, the reaction force analysis (RFA) has been employed. It enables the partition of the reaction coordinate into the reactant, transition state, and product regions where different stages of the mechanism occur. A detailed characterization of the main non-covalent driving forces in the initial stages of the activation of CO by low-valent group 14 complexes was performed using symmetry-adapted perturbation theory (SAPT). The SAPT0-CT/def2-SVP method was employed for these computations. Charge transfer descriptors based on atomic population using the MBIS scheme were also obtained to complement the SAPT analyses.
低价第14族催化剂对CO的活化涉及在单一过渡态中通过协同途径断裂各种共价键。配合物中中心主族原子与氢化物之间的键被拉长,以引发与CO形成C-H键,同时在配合物与CO之间形成E-O键,从而生成相应的甲酸盐产物。先前的研究表明,除了CO的非极性性质外,其与配合物的初始相互作用主要受静电相互作用支配。值得注意的是,在反应初始阶段,其他稳定相互作用以及催化剂与CO之间的电荷转移被忽略了。在本研究中,我们对促进第14族主族配合物活化CO的非共价相互作用和电荷转移进行了量化。我们的研究结果表明,静电相互作用在反应物区域主要稳定配合物和CO。然而,随着反应向过渡态进行,诱导能成为主要的稳定力,超过了静电作用。在过渡态,诱导对稳定性的贡献约为50%,其次是静电作用(40%)和色散相互作用(10%)。用最小基迭代股东(MBIS)方法计算的原子电荷显示,与正面接近相比,CO从背面接近催化剂的反应路径有更大的电荷转移。值得注意的是,发现对于所有体系,CO最初轻微弯曲至约 会引发电荷转移过程。此外,我们对第14族元素的研究表明,在第14族中向下移动时,活化能和向CO的电荷转移都有系统地降低。
所有研究的反应均沿着用内禀反应坐标(IRC)方法在M06-2X/6-31g(d,p)理论水平获得的反应坐标进行表征。甲苯中的吉布斯自由能使用DLPNO-CCSD(T)/cc-pVTZ-SSD(E)理论水平的电子能量进行计算。应用振动和平动熵校正以更准确地描述所获得的吉布斯自由能。为了更好地表征所有反应的反应坐标变化,采用了反应力分析(RFA)。它能够将反应坐标划分为反应物、过渡态和产物区域,反应机理的不同阶段在这些区域发生。使用对称适配微扰理论(SAPT)对低价第14族配合物活化CO初始阶段的主要非共价驱动力进行了详细表征。这些计算采用了SAPT0-CT/def2-SVP方法。还获得了基于使用MBIS方案的原子布居的电荷转移描述符,以补充SAPT分析。
