Josiah B. Barbour scite author profile

Density functional theory was employed to calculate the acidities and hydride abstraction enthalpies of propene (3) and propane (4), along with their vinylogues (5 and 6, respectively). The same reaction enthalpies were calculated for the propene vinylogues in which the terminal vinyl group was rotated perpendicular to the rest of the conjugated system (7). The contribution by resonance and inductive effects toward the acidity and hydride abstraction enthalpy of each vinylogue of 5 (n = 1-3) was computed and extrapolated to n = 0 (the parent propene system). The resonance energies of the allyl cation and anion were determined to be about 20-22 and 17-18 kcal/mol, respectively. Comparisons are made to resonance energies calculated using other methodologies.

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Resonance and field/inductive substituent effects on the gas‐phase acidities of para‐substituted phenols: a direct approach employing density functional theory

Barbour

Karty

2004

J of Physical Organic Chem

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Relative gas‐phase acidities of para‐substituted phenols (1, Sub—C6H4—OH) and their ω‐substituted para‐alkylphenol analogs [2, Sub—(CH2)n—C6H4—OH] were calculated at the B3LYP/6–31+G* and AM1 levels of theory. The acidity of a substituted molecule of 2 is compared with that of the unsubstituted molecule of 2 to determine the field/inductive effect of the substituent on the acidity of 2. This field/inductive effect was extrapolated to n = 0, yielding the field/inductive effect of the substituent on the acidity of 1. The derived field/inductive effect in 1 was subtracted from the difference in acidity between 1 and phenol in order to determine the resonance effect of the substituent on the acidity of 1. Our results are compared with the field/inductive and resonance substituent parameters empirically derived from previous experimental solution studies. Copyright © 2004 John Wiley & Sons, Ltd.

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Li⁺-Catalyzed Radical Polymerization of Simple Terminal Alkenes

Vyakaranam¹,

Barbour²,

Michl³

2009

J. Am. Chem. Soc.

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Josiah B. Barbour

Li⁺-Catalyzed Radical Polymerization of Simple Terminal Alkenes

Resonance Energies of the Allyl Cation and Allyl Anion: Contribution by Resonance and Inductive Effects toward the Acidity and Hydride Abstraction Enthalpy of Propene

Resonance and field/inductive substituent effects on the gas‐phase acidities of para‐substituted phenols: a direct approach employing density functional theory

Li⁺-Catalyzed Radical Polymerization of Simple Terminal Alkenes

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Josiah B. Barbour

Li+-Catalyzed Radical Polymerization of Simple Terminal Alkenes

Resonance Energies of the Allyl Cation and Allyl Anion: Contribution by Resonance and Inductive Effects toward the Acidity and Hydride Abstraction Enthalpy of Propene

Resonance and field/inductive substituent effects on the gas‐phase acidities of para‐substituted phenols: a direct approach employing density functional theory

Li+-Catalyzed Radical Polymerization of Simple Terminal Alkenes

Contact Info

Product

Resources

About

Li⁺-Catalyzed Radical Polymerization of Simple Terminal Alkenes

Li⁺-Catalyzed Radical Polymerization of Simple Terminal Alkenes