Abstract
The reaction rate constants of ozone with 95 alkenes (-logkO3) and the hydroxyl radical (•OH) with 98 alkenes (-logkOH) in the atmosphere were predicted by quantitative structure-activity relationship (QSAR) models. Density functional theory (DFT) calculations were carried out on respective ground-state alkenes and transition-state structures of degradation processes in the atmosphere. Stepwise multiple linear regression (MLR) and general regression neural network (GRNN) techniques were used to develop the models. The GRNN model of -logkO3 based on three descriptors and the optimal spread σ of 0.09 has the mean root mean square (rms) error of 0.344; the GRNN model of -logk OH having four descriptors and the optimal spread σ of 0.14 produces the mean rms error of 0.097. Compared with literature models, the GRNN models in this article show better statistical characteristics. The importance of transition state descriptors in predicting kO3 and kOH of atmospheric degradation processes has been demonstrated.
Highlights
Organic compounds emitted into the atmosphere can result in many adverse effects, such as photochemical air pollution, acid deposition, long-range transport of chemicals, changes of the stratospheric ozone layer and global weather modification, through a complex array of chemical and physical transformations.[1]
Sig.-test suggests that the three descriptors energy of the highest occupied molecular orbital (EGHOMO), QIO12, and qIC12 are significant descriptors and the variance inflation factor (VIF)-test shows that the descriptors are not strongly correlated with each other
quantitative structure-activity relationship (QSAR) models based on the multiple linear regression (MLR) and general regression neural network (GRNN)
Summary
Organic compounds emitted into the atmosphere can result in many adverse effects, such as photochemical air pollution, acid deposition, long-range transport of chemicals, changes of the stratospheric ozone layer and global weather modification, through a complex array of chemical and physical transformations.[1].
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