Structural Consequences of the Addition of Lithium Halides in Enolization and Aldol Reactions

Aggregates consisting of lithium halides with either lithium amides or lithium enolates have been characterized by X-ray crystallography. Two structural types, solvated heterodimers and heterotrimers, have been found for halide/amide combinations. Two compounds containing both lithium halide and lit...

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Bibliographic Details
Published in:Journal of the American Chemical Society 1996-02, Vol.118 (6), p.1339-1347
Main Authors: Henderson, Kenneth W, Dorigo, Andrea E, Liu, Qi-Yong, Williard, Paul G, Schleyer, Paul von Ragué, Bernstein, Peter R
Format: Article
Language:English
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Summary:Aggregates consisting of lithium halides with either lithium amides or lithium enolates have been characterized by X-ray crystallography. Two structural types, solvated heterodimers and heterotrimers, have been found for halide/amide combinations. Two compounds containing both lithium halide and lithium enolate have also been identified as heterodimers. Using this information, we propose a reaction sequence for enolization and subsequent aldol addition reaction involving halide-containing aggregates. An ab initio and PM3 theoretical study of model systems shows that solvated heterodimers between LiBr and either LiNH2 or LiOC(H)=CH2 are favored over the respective homodimers. Calculations reveal a stable eight-membered ring transition state for the enolization step between LiCl·LiNH2 and acetaldehyde. Two independent transition states, a 4,8 and a 4,4,6 ring system, were calculated for the model reaction between the heterotrimer [(LiNH2)2·LiCl] and acetaldehyde. Dissociation of donor solvent was computed to require more energy for heterodimers than for homodimers.
ISSN:0002-7863
1520-5126
DOI:10.1021/ja9527838