摘要
Density functional theory and ab initio calculations have been used to determine structures and stabilities of the protonated aromatics species AH^+ and AH2^2+ (A=pyrrole, furan). Possible mechanisms and relative energetics for protonation of pyrrole and furan by H3O^+ and AH^+ in the gas phase have been explored. Calculations show that the Cα-protonated species was the most stable structure for AH^+, and the protonated AH^+ might accommodate the second proton to yield AH2^2+ if the free proton was available. The gas-phase H3O^+ could protonate pyrrole and furan with significant exothermiCity and almost without barrier. The proton transfer from AH4^+ to pyrrole and furan has a barrier ranging from 33.5 to 39.3 kJ/mol in the gas phase.
Density functional theory and ab initio calculations have been used to determine structures and stabilities of the protonated aromatics species AH^+ and AH2^2+ (A=pyrrole, furan). Possible mechanisms and relative energetics for protonation of pyrrole and furan by H3O^+ and AH^+ in the gas phase have been explored. Calculations show that the Cα-protonated species was the most stable structure for AH^+, and the protonated AH^+ might accommodate the second proton to yield AH2^2+ if the free proton was available. The gas-phase H3O^+ could protonate pyrrole and furan with significant exothermiCity and almost without barrier. The proton transfer from AH4^+ to pyrrole and furan has a barrier ranging from 33.5 to 39.3 kJ/mol in the gas phase.
基金
Project supported by the National Natural Science Foundation of China (Nos. 20173042, 20233020, 20473062 and 20021002), the Ministry of Science and Technology of China (Nos. 2004CB719902 and 001CB 1089) and the Ministry of Education of China.