AI Article Synopsis
- The study investigates the properties of camphorsultam-based lithium enolates, known as Oppolzer enolates, using various scientific methods to understand their alkylation mechanisms and stereoselectivity.
- The research reveals different structural forms of the enolates based on solvent and substrate types, such as tetramers and dimers, emphasizing how these structures change with conditions like solvent concentration.
- Findings indicate that the stereoselectivity arises from the chirality of the sultam ring rather than other structural components, and computational methods help support a model explaining these behaviors without relying on typical coordination theories.
Article Abstract
Camphorsultam-based lithium enolates referred to colloquially as Oppolzer enolates are examined spectroscopically, crystallographically, kinetically, and computationally to ascertain the mechanism of alkylation and the origin of the stereoselectivity. Solvent- and substrate-dependent structures include tetramers for alkyl-substituted enolates in toluene, unsymmetric dimers for aryl-substituted enolates in toluene, substrate-independent symmetric dimers in THF and THF/toluene mixtures, HMPA-bridged trisolvated dimers at low HMPA concentrations, and disolvated monomers for the aryl-substituted enolates at elevated HMPA concentrations. Extensive analyses of the stereochemistry of aggregation are included. Rate studies for reaction with allyl bromide implicate an HMPA-solvated ion pair with a Li(HMPA) counterion. Dependencies on toluene and THF are attributed to exclusively secondary-shell (medium) effects. Aided by density functional theory (DFT) computations, a stereochemical model is presented in which neither chelates nor the lithium gegenion serves roles. The stereoselectivity stems from the chirality within the sultam ring and not the camphor skeletal core.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC10071589 | PMC |
| http://dx.doi.org/10.1021/jacs.2c09341 | DOI Listing |
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Article Synopsis
- The study investigates the properties of camphorsultam-based lithium enolates, known as Oppolzer enolates, using various scientific methods to understand their alkylation mechanisms and stereoselectivity.
- The research reveals different structural forms of the enolates based on solvent and substrate types, such as tetramers and dimers, emphasizing how these structures change with conditions like solvent concentration.
- Findings indicate that the stereoselectivity arises from the chirality of the sultam ring rather than other structural components, and computational methods help support a model explaining these behaviors without relying on typical coordination theories.
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