1. BF3·Et2O-Promoted Decomposition of Cyclic α-Diazo-β-Hydroxy Ketones: Novel Insights into Mechanistic Aspects
- Author
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Emidio Camaioni, Bruno Cerra, Antimo Gioiello, Roberto Pellicciari, Francesco Venturoni, and Maura Marinozzi
- Subjects
Allylic rearrangement ,macromolecular substances ,lcsh:Chemical technology ,010402 general chemistry ,Ring (chemistry) ,alpha-diazo-beta-hydroxy ketones ,decomposition ,vinyl cation cascade ,diazoacetone ,borontrifluoride ,01 natural sciences ,Medicinal chemistry ,Catalysis ,lcsh:Chemistry ,chemistry.chemical_compound ,lcsh:TP1-1185 ,Lewis acids and bases ,Physical and Theoretical Chemistry ,010405 organic chemistry ,Chemistry ,organic chemicals ,technology, industry, and agriculture ,0104 chemical sciences ,Solvent ,Ring size ,lcsh:QD1-999 ,Hydroxide ,Diazo ,Vinyl cation ,α-diazo-β-hydroxy ketones - Abstract
We report novel insights into the cascade rearrangement of destabilized vinyl cations deriving from the BF3·, Et2O-induced decomposition of cyclic &alpha, diazo-&beta, hydroxy ketones in turn prepared by aldol-type condensation of cycloalkanones with diazoacetone. Complexation of the hydroxy group of the &alpha, hydroxy compound with the Lewis acid is the first event, followed by the generation of the cycloalkanylidenediazonium salt that, after nitrogen loss, produces the highly reactive vinyl cation. The subsequent ring expansion results in the formation of a cycloalkenyl vinyl cation that affords the allylic cation by 1,2-methylene shift and ring contraction. The cation can then trap the solvent, the fluoride or the hydroxide released from the [BF3OH]&minus, to afford different reaction products. The effect of both solvent and substrate ring size on products types and ratios were analyzed and discussed from a mechanistic point of view.
- Published
- 2018