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Almost 30 years after Emschwiller prepared IZnCH 2 I, Simmons and Smith discovered that the reagent formed by mixing a zinc‐copper couple with CH 2 I 2 in ether could be used for the stereospecific conversion of alkenes to cyclopropanes. Nowadays, the Simmons‐Smith cyclopropanation reaction is one of the most widely used reactions in the organic chemist's arsenal for the conversion of olefins into cyclopropanes. This popularity is mainly due to the stereospecificity of the reaction with respect to the double bond geometry and its compatibility with a wide range of functional groups. The chemoselectivity of the reaction toward some olefins is excellent and very few side reactions are observed with functionalized substrates. The metal carbenoid is electrophilic in nature and electron‐rich alkenes usually react much faster than electron‐poor alkenes. Furthermore, the ability to use proximal hydroxy or ether groups to dictate the stereochemical outcome of the CC bond forming process was recognized early on, and this unique property has been successfully exploited on numerous occasions. It has been recognized that halomethylmetal reagents are powerful synthetic tools for the stereoselective addition of a methylene unit to chiral acyclic allylic alcohols and allylic ethers. In addition, the use of halomethylzinc reagents in the presence of chiral additives is one of the few ways to cyclopropanate allylic alcohols efficiently and with good enantiocontrol. Carbenoids can be divided into the following two classes: (1) those of general structure MCH 2 X and (2) those corresponding to M = CH 2 . This chapter is focussed exclusively on the first class in which M = Zn, Sm, or Al. Although other metal carbenoids of type MCH 2 X, such as those derived from Cu, Cd, Hg, and In, have been reported to be effective reagents for the cyclopropanation of some olefins, they have been used only sporadically, and this review does not highlight these reactions. This chapter covers cyclopropanation reactions involving haloalkylzinc, aluminum, and samarium reagents published since the comprehensive chapter in Organic Reactions by Simmons that surveyed the literature up to 1973.
Almost 30 years after Emschwiller prepared IZnCH 2 I, Simmons and Smith discovered that the reagent formed by mixing a zinc‐copper couple with CH 2 I 2 in ether could be used for the stereospecific conversion of alkenes to cyclopropanes. Nowadays, the Simmons‐Smith cyclopropanation reaction is one of the most widely used reactions in the organic chemist's arsenal for the conversion of olefins into cyclopropanes. This popularity is mainly due to the stereospecificity of the reaction with respect to the double bond geometry and its compatibility with a wide range of functional groups. The chemoselectivity of the reaction toward some olefins is excellent and very few side reactions are observed with functionalized substrates. The metal carbenoid is electrophilic in nature and electron‐rich alkenes usually react much faster than electron‐poor alkenes. Furthermore, the ability to use proximal hydroxy or ether groups to dictate the stereochemical outcome of the CC bond forming process was recognized early on, and this unique property has been successfully exploited on numerous occasions. It has been recognized that halomethylmetal reagents are powerful synthetic tools for the stereoselective addition of a methylene unit to chiral acyclic allylic alcohols and allylic ethers. In addition, the use of halomethylzinc reagents in the presence of chiral additives is one of the few ways to cyclopropanate allylic alcohols efficiently and with good enantiocontrol. Carbenoids can be divided into the following two classes: (1) those of general structure MCH 2 X and (2) those corresponding to M = CH 2 . This chapter is focussed exclusively on the first class in which M = Zn, Sm, or Al. Although other metal carbenoids of type MCH 2 X, such as those derived from Cu, Cd, Hg, and In, have been reported to be effective reagents for the cyclopropanation of some olefins, they have been used only sporadically, and this review does not highlight these reactions. This chapter covers cyclopropanation reactions involving haloalkylzinc, aluminum, and samarium reagents published since the comprehensive chapter in Organic Reactions by Simmons that surveyed the literature up to 1973.
The intramolecular thermolysis of organic compounds with an unsaturated functional group involving the transfer of a γ‐hydrogen to the unsaturated center via a six‐membered transition state to yield both ene and enophil is generally known as the retro ‐ene reaction or retro ‐ene fragmentation. The study finds that in most cases, this reaction involves a concerted mechanism, and gives a product with the stereochemical integrity preserved. This reaction does not take place among cyclic alkenes smaller than a seven‐membered ring or fused rings except for a cyclopropyl ring. This reaction has broad applications in organic synthesis.
Aus 1‐Acety1‐2‐methyl‐cyclohexen (I) wird in der angegebenen Weise das Cyclopropyl‐keton (IV) hergestellt und dieses bei 200°C pyrolysiert.
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