A theoretical approach to substituent effects. Stabilities and conformational preferences in β-substituted ethyl radicals

Addy Pross; Leo Radom

doi:10.1016/0040-4020(80)80213-4

A theoretical approach to substituent effects. Stabilities and conformational preferences in β-substituted ethyl radicals

Addy Pross, Leo Radom

Research output: Contribution to journal › Article › peer-review

30 Scopus citations

Abstract

Ab initio molecular orbital theory is used to study substituent effects in a series of β-substituted Et radicals XCH₂CH₂. For X = BH₂ (plan.), CH₃, NH₂, OH and F, only slight conformational preferences and weak stabilizations are indicated. Such behaviour may be rationalized, using a PMO model, in terms of opposing changes, accompanying variation in X, in positive and negative hyperconjugation between the XCH₂ group and the CH₂ centre. On the other hand, for groups containing an appropriately oriented, low-lying vacant orbital, viz. X = Li, BeH and BH₂ (perp.), there is a pronounced preference for the perpendicular conformation of the radical. This is attributed to 1,3-interaction between the singly-occupied 2p(C) orbital and the vacant 2p(X) orbital.

Original language	English
Pages (from-to)	1999-2003
Number of pages	5
Journal	Tetrahedron
Volume	36
Issue number	13
DOIs	https://doi.org/10.1016/0040-4020(80)80213-4
State	Published - 1 Jan 1980
Externally published	Yes

ASJC Scopus subject areas

Biochemistry
Drug Discovery
Organic Chemistry

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title = "A theoretical approach to substituent effects. Stabilities and conformational preferences in β-substituted ethyl radicals",

abstract = "Ab initio molecular orbital theory is used to study substituent effects in a series of β-substituted Et radicals XCH2CH2. For X = BH2 (plan.), CH3, NH2, OH and F, only slight conformational preferences and weak stabilizations are indicated. Such behaviour may be rationalized, using a PMO model, in terms of opposing changes, accompanying variation in X, in positive and negative hyperconjugation between the XCH2 group and the CH2 centre. On the other hand, for groups containing an appropriately oriented, low-lying vacant orbital, viz. X = Li, BeH and BH2 (perp.), there is a pronounced preference for the perpendicular conformation of the radical. This is attributed to 1,3-interaction between the singly-occupied 2p(C) orbital and the vacant 2p(X) orbital.",

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AU - Pross, Addy

AU - Radom, Leo

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N2 - Ab initio molecular orbital theory is used to study substituent effects in a series of β-substituted Et radicals XCH2CH2. For X = BH2 (plan.), CH3, NH2, OH and F, only slight conformational preferences and weak stabilizations are indicated. Such behaviour may be rationalized, using a PMO model, in terms of opposing changes, accompanying variation in X, in positive and negative hyperconjugation between the XCH2 group and the CH2 centre. On the other hand, for groups containing an appropriately oriented, low-lying vacant orbital, viz. X = Li, BeH and BH2 (perp.), there is a pronounced preference for the perpendicular conformation of the radical. This is attributed to 1,3-interaction between the singly-occupied 2p(C) orbital and the vacant 2p(X) orbital.

AB - Ab initio molecular orbital theory is used to study substituent effects in a series of β-substituted Et radicals XCH2CH2. For X = BH2 (plan.), CH3, NH2, OH and F, only slight conformational preferences and weak stabilizations are indicated. Such behaviour may be rationalized, using a PMO model, in terms of opposing changes, accompanying variation in X, in positive and negative hyperconjugation between the XCH2 group and the CH2 centre. On the other hand, for groups containing an appropriately oriented, low-lying vacant orbital, viz. X = Li, BeH and BH2 (perp.), there is a pronounced preference for the perpendicular conformation of the radical. This is attributed to 1,3-interaction between the singly-occupied 2p(C) orbital and the vacant 2p(X) orbital.

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JO - Tetrahedron

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ER -

A theoretical approach to substituent effects. Stabilities and conformational preferences in β-substituted ethyl radicals

Abstract

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