Theoretical investigation of sulfur and halogen-substituted carbocations

Paul Kiprof; Stephen R. Miller; Melissa A. Frank

doi:10.1016/j.theochem.2006.02.009

Theoretical investigation of sulfur and halogen-substituted carbocations

Paul Kiprof, Stephen R. Miller, Melissa A. Frank

Chemistry & Biochemistry

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11 Scopus citations

Abstract

The stabilization of sulfur, fluorine and chlorine substituted carbocations was studied using hydride exchange reactions at the G2 level of theory; evaluation of the π bonding in these was performed using variation of the dihedral angle in the case of sulfur compounds and NRT and other bond order calculations for all compounds. Resonance contributors were estimated using the NRT method. Sulfur substitution stabilizes carbocations comparable to oxygen substitution covered previously. The stability of trisubstituted carbocations is enhanced over the oxygen analogues. Halogen substitution leads to destabilization, which is more extreme for the fluorine-substituted carbocations.

Original language	English (US)
Pages (from-to)	61-67
Number of pages	7
Journal	Journal of Molecular Structure: THEOCHEM
Volume	764
Issue number	1-3
DOIs	https://doi.org/10.1016/j.theochem.2006.02.009
State	Published - May 30 2006

Keywords

Bond order
Carbocation
Chlorine
Fluorine
G2
Hydride exchange
NBO
NRT
Resonance
Sulfur

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title = "Theoretical investigation of sulfur and halogen-substituted carbocations",

abstract = "The stabilization of sulfur, fluorine and chlorine substituted carbocations was studied using hydride exchange reactions at the G2 level of theory; evaluation of the π bonding in these was performed using variation of the dihedral angle in the case of sulfur compounds and NRT and other bond order calculations for all compounds. Resonance contributors were estimated using the NRT method. Sulfur substitution stabilizes carbocations comparable to oxygen substitution covered previously. The stability of trisubstituted carbocations is enhanced over the oxygen analogues. Halogen substitution leads to destabilization, which is more extreme for the fluorine-substituted carbocations.",

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AU - Frank, Melissa A.

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AB - The stabilization of sulfur, fluorine and chlorine substituted carbocations was studied using hydride exchange reactions at the G2 level of theory; evaluation of the π bonding in these was performed using variation of the dihedral angle in the case of sulfur compounds and NRT and other bond order calculations for all compounds. Resonance contributors were estimated using the NRT method. Sulfur substitution stabilizes carbocations comparable to oxygen substitution covered previously. The stability of trisubstituted carbocations is enhanced over the oxygen analogues. Halogen substitution leads to destabilization, which is more extreme for the fluorine-substituted carbocations.

KW - Bond order

KW - Carbocation

KW - Chlorine

KW - Fluorine

KW - G2

KW - Hydride exchange

KW - NBO

KW - NRT

KW - Resonance

KW - Sulfur

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Theoretical investigation of sulfur and halogen-substituted carbocations

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