The linear conjugated compounds are a class of important organic compounds with good ultraviolet (UV) absorption, which are usually employed as the parent molecules of a lot of optical materials. The traditional topological quantum chemistry approach can accurately predict the UV absorption energies of unsubstituted linear conjugated alkenes. However, for the alkyl-substituted conjugated alkenes, this approach seems unsatisfactory. It is known that the it conjugated chain is a good conductor for the electron mobility, while the alkyl substituent is a bad one. As a result, their influences on the pi electron transition will be different from each other. In order to distinguish the contribution of these two different structural parts, a substructure approach was proposed, in which a substituted linear conjugated molecule was divided into two substructures: the pi conjugated chain part and the substituent part. Different methods were employed to characterize their structures. The relative frontier orbital energy gap of the conjugated chain (Delta REHL0) and the polarization energy of the substituents (P-RE) were calculated by substructure-based topological quantum chemistry method. A good linear regression model was built between the UV absorption wavenumbers and two parameters Delta REHL0, and PRE for 23 typical conjugated alkenes. Based on this model, the UV absorption wavenumbers of other 70 alkenes were also predicted with high accuracy. This substructure-based topological quantum chemistry method was also extended to the investigation of the UV absorption of 89 olefinic aldehydes and ketones, and good results were also obtained.

• 出版日期2016-11-15
• 单位湖南科技大学; 湖南大学