Dynamic Effects Dictate the Mechanism and Selectivity of Dehydration-Rearrangement Reactions of Protonated Alcohols [Me sub(2)(R)CCH(OH sub(2))Me] super(+) (R=Me, Et, iPr) in the Gas Phase

The gas-phase dehydration-rearrangement (DR) reactions of protonated alcohols [Me sub(2)(R)CCH(OH sub(2))Me] super(+) [R=Me (ME), Et (ET), and iPr (I-PR)] were studied by using static approaches (intrinsic reaction coordinate (IRC), Rice-Ramsperger-Kassel-Marcus theory) and dynamics (quasiclassical...

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Bibliographic Details
Published in:Chemistry : a European journal 2014-10, Vol.20 (42), p.13742-13754
Main Authors: deSouza, Miguel AF, Ventura, Elizete, Monte, Silmar Ado, Riveros, Jose M, Longo, Ricardo L
Format: Article
Language:English
Subjects:
Alcohols
Dehydration
Dynamic tests
Dynamics
Migration
Pathways
Selectivity
Simulation
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Summary:The gas-phase dehydration-rearrangement (DR) reactions of protonated alcohols [Me sub(2)(R)CCH(OH sub(2))Me] super(+) [R=Me (ME), Et (ET), and iPr (I-PR)] were studied by using static approaches (intrinsic reaction coordinate (IRC), Rice-Ramsperger-Kassel-Marcus theory) and dynamics (quasiclassical trajectory) simulations at the B3LYP/6-31G(d) level of theory. The concerted mechanism involves simultaneous water dissociation and alkyl migration, whereas in the stepwise reaction pathway the dehydration step leads to a secondary carbocation intermediate followed by alkyl migration. Internal rotation (IR) can change the relative position of the migrating alkyl group and the leaving group (water), so distinct products may be obtained: [Me(R)CCH(Me)MeOH sub(2)] super(+) and [Me(Me)CCH(R)MeOH sub(2)] super(+). The static approach predicts that these reactions are concerted, with the selectivity towards these different products determined by the proportion of the conformers of the initial protonated alcohols. These selectivities are explained by the DR processes being much faster than IR. These results are in direct contradiction with the dynamics simulations, which indicate a predominantly stepwise mechanism and selectivities that depend on the alkyl groups and dynamics effects. Indeed, despite the lifetimes of the secondary carbocations being short (
ISSN:0947-6539
1521-3765
DOI:10.1002/chem.201402617