A QSPR Study of the ³¹P NMR Chemical Shifts of Phosphines

Quantitative structure−property relationships (QSPR) on a large set of descriptors are developed for the ³¹P NMR chemical shifts of a large set of phosphines. The data set was composed of 291 primary, secondary, and tertiary phosphines, PH_3-nR_n, including substituents with different steric and electronic characteristics. Multiple linear regression and computational neural networks (CNN) were employed to create the models best suited for the prediction of ³¹P NMR chemical shifts. A correlation equation including seven descriptors (R² = 0.8619) is reported. A 7-5-1 CNN was developed that produced a root-mean-error of 9.6 ppm (R² = 0.9513) for the training set, of 11.7 ppm (R² = 0.8986) for the cross-validation set, and of 11.3 ppm (R² = 0.9527) for an external prediction set. The CNN methods give significantly better predictions of ³¹P NMR chemical shifts for phosphines than the multiple linear regression approach.