Carbocationic Cyclopropanation Using Tin

 

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Abstract

γ-Effects of group 14 elements such as silicon and tin is discussed with the emphasis on the comparison with β-effects. Based on the striking γ-effect of tin, cyclopropantion reactions of alkenes using organotin compounds have been developed. Using ­allyl group 14 element compounds as alkenes, intramolecular ­competition between β-elimination and γ-elimination of group 14 elements has been studied. Intermolecular competition has also been examined using the reaction of allyl- and homoallyl group 14 element compounds with electrophiles. As an application of the present method in organic synthesis, intramolecularization of ­cationic cyclopropanation based on in-situ transacetalization to form unique cyclopropane structures is demonstrated.

1 Introduction

2 Control of Carbocationic Reactions Using Group 14 ­Elements

2.1 β-Effect of Silicon

2.2 β-Effect and γ-Effect of Group 14 Elements

2.3 γ-Elimination of Group 14 Elements

3 Carbocationic Cyclopropantion of Alkenes Using Tin

3.1 Carbocationic Cyclopropanation of Alkenes Using Tin-Substituted Carbonates

3.2 Carbocationic Cyclopropanation of Alkenes Using Tin-Substituted Acetals

4 Intramolecular Competition between β-Effect and γ-Effect of Group 14 Elements

5 Intermolecular Competition between β-Effect and γ-Effect of Group 14 Elements

6 Intramolecularization of Carbocationic Cyclopropanation Using Tin

7 Conclusion

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