Methylene-3-halo

Aziridine, 2,3-diphenyl-l-(2,4,6-trinitrophenyl)-irradiation, 7, 61 Aziridine, 1,2-divinyl-rearrangement, 7, 539 Aziridine, 2,3-divinyl-rearrangement, 7, 42, 65, 539 Aziridine, N-ethyl-inversion, 7, 6 Aziridine, 2-halo-reactions, 7, 74 Aziridine, A/-halo-invertomers, 7, 6 Aziridine, 2-methyl- N NMR, 7, 11 Aziridine, methylene-ring-ring valence isomerizations, 7, 22 synthesis, 7, 92 Aziridine, iV-nitroso-reactions, 7, 74 Aziridine, iV-phosphino-inversion, 7, 7 Aziridine, 1-phthalimido-UV irradiation, 7, 62-63 Aziridine, l-(3-thienyl)-2-vinyl-rearrangement, 4, 746 Aziridine, 7V-trimethylsilyl-inversion, 7, 7 Aziridine, 1,2,3-triphenyl-irradiation, 7, 61 Aziridine, vinyl-isomerization, S, 287 Aziridinecarboxylic acid ring expansion, 7, 262 Aziridine-2,2-dicarboxylic acid, 1-methoxy-diethyl ester... 

The influence of the halogen on the mechanistic course of carbanionic rearrangement of 3-hexylhalomethylenecyclobutanes (Scheme 11, X = F, Cl, Br, I) to l-halo-4-hexylcyclopentenes has been explored by studying the fate of C-labelled methylene... 

The correctness of the conclusions reached in this study were confirmed by a recent report on the explosions of mixtures containing halo-genated solvents (such as methylene chloride) and nitrogen tetroxide. 

Vinyl ethers have also been prepared by addition of alkoxides to acetylene,6 7 6 elimination from halo ethers and related precursors,6 8 and vinyl exchange reactions.6 Reaction of an electrophilic tungsten carbenoid with methylene phosphorane or diazomethane also produces vinyl ethers.9 Enol ethers have resulted from the reaction of some tantalum and niobium carbenoids with esters,10 and the reaction of phosphoranes with electrophilic esters.4... 

Clemmensen-type reduction.1 Aromatic ketones can be reduced to the corresponding methylene compounds with ammonium formate on transfer hydrogenation in acetic acid catalyzed by 10% Pd/C. The reduction is usually complete in 10-30 minutes at 110°. Halo and nitro substituents can be reduced under these conditions, and a,p-unsaturated carbonyl groups are reduced to saturated carbonyl groups. 

Of all the methods described for the synthesis of thiazole compounds, the most efficient involves the condensation of equimolar quantities of thiourea and a-halo ketones or aldehydes to yield the corresponding 2-aminothiazoles (Scheme 167) (l888LA(249)3l). The reaction occurs more readily than that of thioamides and can be carried out in aqueous or alcoholic solution, even in a distinctly acid medium, an advantage not shared by thioamides which are often unstable in acids. The yields are usually excellent. A derived method condenses the thiourea (2 mol) with the non-halogenated methylene ketone (1 mol) in the presence of iodine (1 mol) or another oxidizing agent (chlorine, bromine, sulfuryl chloride, chlorosulfonic acid or sulfur monochloride) (Scheme 168) (45JA2242). 

The 5-position in 1,2,4-thiadiazoles is most reactive in nucleophilic substitution reactions. Chlorine, for example, may be displaced by nucleophiles (Nu) such as fluoride, hydroxide, thiol, amino, hydrazino, sulfite and azido groups (Scheme 11). Active methylene compounds such as malonic, acetoacetic and cyanoactic esters as their sodio derivatives also displace the 5-halo substituent (65AHC(5)ll9). The reaction follows second-order kinetics, the rate determining step being addition of the nucleophile at C-5 followed by rapid elimination of X. 

However, difficulties caused by isomerisation of the halo-compounds during the reaction gave rise to results which are only approximate, except for X = F. It was observed that deuteriation of the methylene group is preferred for X = Cl, while under the same conditions fluoroacetone deuteriates preferentially at the methyl group (kjkj 10). 

The preparation of a-thiolated acroleins2) and the methylene lactone annu-lation S3) by Hiyama et al. are two further examples of the applications of a-halo-cyclopropyllithium derivatives which have to be handled at temperatures well below dry ice temperature (Eqs. (47) and (48)). 

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