The kinetics and the stereochemistry of the protonation-induced unimolecular isomerization of (S)-(+)-1-D-1-3-(p-tolyl)butane have been investigated in the, gas phase in the 100-160degreesC range. The process leads to the almost exclusive formation of the relevant meta isomer with complete racemization and partial 1,2-H shift in the migrating sec-butyl group. These results, together with the relevant activation parameters, point to the occurrence of low-energy, tightly bound isomeric sec-butyl cation/toluene complexes of defined structure and stability along the isomerization coordinate. The existence and the eta(1)-type structure of these low-energy intermediate species are confirmed by ab initio calculations on closely related systems at the MP2(full)/6-3l1++G**//HF/6-31 + G** level of theory. Their role in the relevant energy surface clearly emerges from the comparison of the present results with those concerning sec-butylation of toluene carried out under comparable experimental conditions.
Isomeric alkyl cation/arene complexes in the gas phase / Filippi, Antonello; Graziella, Roselli; Gabriele, Renzi; Felice, Grandinetti; Speranza, Maurizio. - In: CHEMISTRY-A EUROPEAN JOURNAL. - ISSN 0947-6539. - STAMPA. - 9:9(2003), pp. 2072-2078. [10.1002/chem.200204281]
Isomeric alkyl cation/arene complexes in the gas phase
FILIPPI, Antonello;SPERANZA, Maurizio
2003
Abstract
The kinetics and the stereochemistry of the protonation-induced unimolecular isomerization of (S)-(+)-1-D-1-3-(p-tolyl)butane have been investigated in the, gas phase in the 100-160degreesC range. The process leads to the almost exclusive formation of the relevant meta isomer with complete racemization and partial 1,2-H shift in the migrating sec-butyl group. These results, together with the relevant activation parameters, point to the occurrence of low-energy, tightly bound isomeric sec-butyl cation/toluene complexes of defined structure and stability along the isomerization coordinate. The existence and the eta(1)-type structure of these low-energy intermediate species are confirmed by ab initio calculations on closely related systems at the MP2(full)/6-3l1++G**//HF/6-31 + G** level of theory. Their role in the relevant energy surface clearly emerges from the comparison of the present results with those concerning sec-butylation of toluene carried out under comparable experimental conditions.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
