Conformation design of hydrocarbon backbones: A modular approach

Reinhard W. Hoffmann; Martin Stahl; Ulrich Schopfer; Gernot Frenking

doi:10.1002/(SICI)1521-3765(19980416)4:4<559::AID-CHEM559>3.0.CO;2-T

Conformation design of hydrocarbon backbones: A modular approach

Reinhard W. Hoffmann, Martin Stahl, Ulrich Schopfer, Gernot Frenking

University of Marburg

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

67 Scopus citations

Abstract

A modular approach towards a conformation design of hydrocarbon backbones is described. The idea is to attach substituents (e.g., methyl branches) to a hydrocarbon backbone in such a manner that they create destabilizing syn-pentane interactions in all but one diamond-lattice backbone conformation. This creates a substantial (> 7 kJ mol^-1) energy gap between the lowest energy conformer and the higher energy conformers. In consequence, the lowest energy conformer will be populated to a high extent (e.g., > 80%). Small hydrocarbon modules that fulfil this requirement have been identified in a systematic manner, highlighting the role of inductor groups to control the conformation at neighboring skeletal bonds. These modules can in turn serve as inductor groups for more extended hydrocarbon chains, or they may be combined with one another to form larger monoconformational hydrocarbon structures.

Original language	English
Pages (from-to)	559-566
Number of pages	8
Journal	Chemistry - A European Journal
Volume	4
Issue number	4
DOIs	https://doi.org/10.1002/(SICI)1521-3765(19980416)4:4<559::AID-CHEM559>3.0.CO;2-T
State	Published - Apr 1998
Externally published	Yes

Keywords

Ab initio calculations
Conformation analysis
Heterocycles
Hydrocarbons
Steric hindrance

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10.1002/(SICI)1521-3765(19980416)4:4<559::AID-CHEM559>3.0.CO;2-T

Cite this

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abstract = "A modular approach towards a conformation design of hydrocarbon backbones is described. The idea is to attach substituents (e.g., methyl branches) to a hydrocarbon backbone in such a manner that they create destabilizing syn-pentane interactions in all but one diamond-lattice backbone conformation. This creates a substantial (> 7 kJ mol-1) energy gap between the lowest energy conformer and the higher energy conformers. In consequence, the lowest energy conformer will be populated to a high extent (e.g., > 80%). Small hydrocarbon modules that fulfil this requirement have been identified in a systematic manner, highlighting the role of inductor groups to control the conformation at neighboring skeletal bonds. These modules can in turn serve as inductor groups for more extended hydrocarbon chains, or they may be combined with one another to form larger monoconformational hydrocarbon structures.",

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author = "Hoffmann, {Reinhard W.} and Martin Stahl and Ulrich Schopfer and Gernot Frenking",

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AU - Stahl, Martin

AU - Schopfer, Ulrich

AU - Frenking, Gernot

PY - 1998/4

Y1 - 1998/4

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AB - A modular approach towards a conformation design of hydrocarbon backbones is described. The idea is to attach substituents (e.g., methyl branches) to a hydrocarbon backbone in such a manner that they create destabilizing syn-pentane interactions in all but one diamond-lattice backbone conformation. This creates a substantial (> 7 kJ mol-1) energy gap between the lowest energy conformer and the higher energy conformers. In consequence, the lowest energy conformer will be populated to a high extent (e.g., > 80%). Small hydrocarbon modules that fulfil this requirement have been identified in a systematic manner, highlighting the role of inductor groups to control the conformation at neighboring skeletal bonds. These modules can in turn serve as inductor groups for more extended hydrocarbon chains, or they may be combined with one another to form larger monoconformational hydrocarbon structures.

KW - Ab initio calculations

KW - Conformation analysis

KW - Heterocycles

KW - Hydrocarbons

KW - Steric hindrance

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Conformation design of hydrocarbon backbones: A modular approach

Abstract

Keywords

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