d'Antuono Philippe, Botek Edith, Champagne Benoît, Wieme Joris, Reyniers Marie-Françoise, Marin Guy B, Adriaensens Peter J, Gelan Jan M
Laboratoire de Chimie Théorique Appliquée, Facultés Universitaires Notre-Dame de la Paix, Namur, Belgium.
J Phys Chem B. 2008 Nov 27;112(47):14804-18. doi: 10.1021/jp805676q.
1H and 13C chemical shifts of PVC chains have been evaluated using quantum chemistry methods in order to evidence and interpret the NMR signatures of chains bearing unsaturated and branched defects. The geometrical structures of the stable conformers have been determined using molecular mechanics and the OPLS force field and then density functional theory with the B3LYP functional and the 6-311G(d) basis set. The nuclear shielding tensor has been calculated at the coupled-perturbed Kohn-Sham level (B3LYP exchange-correlation functional) using the 6-311+G(2d,p) basis set. The computational scheme accounts for the large number of stable conformers of the PVC chains, and average chemical shifts are evaluated using the Maxwell-Boltzmann distribution. Moreover, the chemical shifts are corrected for the inherent and rather systematic errors of the method of calculation by employing linear regression equations, which have been deduced from comparing experimental and theoretical results on small alkane model compounds containing Cl atoms and/or unsaturations. For each type of defect, PVC segments presenting different tacticities have been considered because it is known from linear PVC chains that the racemic (meso) dyads are characterized by larger (smaller) chemical shifts. NMR signatures of unsaturations in PVC chains have been highlighted for the internal -CH=CH- and -CH=CCl- units as well as for terminal unsaturations like the chloroallylic -CH=CH-CH2Cl group. In particular, the 13C chemical shifts of the two sp2 C atoms are very close for the chloroallylic end group. The CH2 and CHCl units surrounding an unsaturation present also specific 13C chemical shifts, which allow distinguishing them from the others. In the case of the proton, the CH2 unit of the -CHCl-CH2-CCl=CH- segment presents a larger chemical shift (2.6-2.7 ppm), while some CHCl units close to the -CH=CH- unsaturations appear at rather small chemical shifts (3.7 ppm). The -CH2Cl and -CHCl-CH2Cl branches also display specific signatures, which result in large part from modifications of the equilibrium conformations and their reduced number owing to the increased steric interactions. These branches lead to the appearance of 13C peaks at lower field associated either to the CH unit linking the -CH2Cl and -CHCl-CH2Cl branches (50 ppm) or to the CHCl unit of the ethyl branches (60 ppm). The corresponding protons resonate also at specific frequencies: 3.5-4.0 ppm for the -CH2Cl branch or 3.8-4.2 ppm for the terminal unit of the -CHCl-CH2Cl branch. Several of these signatures have been detected in the experimental 1H and 13C NMR spectra and are consistent with the reaction mechanisms.
为了证明并解释带有不饱和和支化缺陷链的核磁共振特征,已使用量子化学方法评估了聚氯乙烯(PVC)链的1H和13C化学位移。利用分子力学和OPLS力场确定了稳定构象体的几何结构,然后使用B3LYP泛函和6-311G(d)基组的密度泛函理论进行了计算。在耦合微扰的Kohn-Sham水平(B3LYP交换相关泛函)下,使用6-311+G(2d,p)基组计算了核屏蔽张量。该计算方案考虑了PVC链大量的稳定构象体,并使用麦克斯韦-玻尔兹曼分布评估了平均化学位移。此外,通过采用线性回归方程对计算方法中固有的且较为系统的误差进行了化学位移校正,这些方程是通过比较含氯原子和/或不饱和键的小烷烃模型化合物的实验和理论结果推导出来的。对于每种类型的缺陷,考虑了具有不同立构规整度的PVC链段,因为从线性PVC链可知,外消旋(内消旋)二元组的特征是化学位移较大(较小)。已突出显示了PVC链中不饱和键的核磁共振特征,包括内部的-CH=CH-和-CH=CCl-单元以及末端不饱和键,如氯代烯丙基-CH=CH-CH2Cl基团。特别是,氯代烯丙基端基的两个sp2碳原子的13C化学位移非常接近。围绕不饱和键的CH2和CHCl单元也呈现出特定的13C化学位移,这使得它们能够与其他单元区分开来。对于质子而言,-CHCl-CH2-CCl=CH-链段的CH2单元呈现出较大的化学位移(2.6 - 2.7 ppm),而一些靠近-CH=CH-不饱和键的CHCl单元出现在相当小的化学位移处(3.7 ppm)。-CH2Cl和-CHCl-CH2Cl支链也显示出特定的特征,这在很大程度上是由于平衡构象的改变以及由于空间相互作用增加导致其数量减少所致。这些支链导致在较低场出现13C峰,这与连接-CH2Cl和-CHCl-CH2Cl支链的CH单元(50 ppm)或乙基支链的CHCl单元(60 ppm)有关。相应的质子也在特定频率处共振:-CH2Cl支链为3.5 - 4.0 ppm,-CHCl-CH2Cl支链的末端单元为3.8 - 4.2 ppm。在实验的1H和13C核磁共振谱中检测到了其中几种特征,并且与反应机理一致。
