Preparation dichlorocarbene

Schiff base 293 with dichlorocarbene, prepared from chloroform and potassium hydroxide in situ, in the presence of benzyltriethylammonium chloride afforded 2-chloro-3-phenyl-l //-pyrimido[l, 2-a]quinolin-l-one (294), l-chloro-2-phenylimidazo[l,2-a]quinoline, and l-(l-quinolyl)-2,2-dichloro-3-phenylaziridine in 5%, 8%, and 6% yields, respectively (91KGS810). 

Apparatus Ketene generator (500 ml distillation flask) (see Ref. 20, p. 529) for. the preparation of tetramethylallene 1-1 round-bottomed, three-necked flask, provided with a mechanical stirrer, a thermometer and a vent for the addition of dichlorocarbene 500-ml flask (see Fig. 1) for the dechlorination. 

The benzyne adducts prepared from A -methylpyrrole (and A -methylisoindole) are deaminated conveniently by dichlorocarbene generated under phase-transfer conditions (81JOC1025 to give a convenient route to substituted naphthalenes (134) (and anthracenes) (Scheme 49). 

Contents Introduction and Principles. - The Reaction of Dichlorocarbene With Olefins. - Reactions of Dichlorocarbene With Non-Olefinic Substrates. -Dibromocarbene and Other Carbenes. - Synthesis of Ethers. - Synthesis of Esters. - Reactions of Cyanide Ion. - Reactions of Superoxide Ions. - Reactions of Other Nucleophiles. - Alkylation Reactions. - Oxidation Reactions. - Reduction Techniques. - Preparation and Reactions of Sulfur Containing Substrates. -Ylids. - Altered Reactivity. - Addendum Recent Developments in Phase Transfer Catalysis. 

Carbon tetrachloride was also found to react with pyrryl potassium to give 3-chloropyridine, however the mechanism is obscure and would justify further investigation. In a preparatively useful reaction, pyrrole and chloroform in the vapor phase at 500-550° gave 3-chloro-pyridine (33%) and a little 2-chloropyridine (2-5%). No interconversion of the isomers occurred under these conditions, though pyrolytic rearrangement of N-alkylpyrrole to 3-substituted pyridines is considered to involve 2-alkylpyrroles as intermediates. There is some independent evidence that dichlorocarbene is formed in the vapor phase decomposition of chloroform. ... 

Starting from l.l-dichloro-7b-ethoxy-2-methyl-1,1 a,2,7-tetrahydrobenzo[/)]cyclopropa[prepared from the corresponding benzothiopyran by addition of dichlorocarbene, the three 1-benzothiepins 6a-c are formed upon treatment with strong bases, i.e. sodium methoxide or ethoxide in dimethyl sulfoxide.73 The optimal yield of each 1-benzo-thiepin compound depends on the molar equivalents of base, as follows from different ring-opening mechanisms. 

Gaoni has published197 a novel preparation of 1,3- and 1,4-dienylic sulphoxides in which certain sulpholenes or sulpholanes can be cleaved with two equivalents of a Grignard reagent. The reactions outlined in equation (86) can be classified formally as a double reduction at the sulphur atom. The 1,4-dienylic sulphoxides can be obtained by the same type of reactions, via bicyclo[3.1.0] sulphones, that are accessible from the sulpholenes and dichlorocarbene, followed by dechlorination with LiAlH4197. Yields for all the reactions are poor to modest (26 to 66%). 

The present method utilizes dichlorocarbene generated by the phase-transfer method of Makosza4 and Starks.5 The submitters have routinely realized yields of pure distilled isocyanides in excess of 40%.6 With less sterically hindered primary amines a 1 1 ratio of amine to chloroform gives satisfactory results. Furthermore, by modifying the procedure, methyl and ethyl isocyanides may be prepared directly from the corresponding aqueous amine solutions and bromoform.7 These results are summarized in Table I. 

Various synthetic routes to isocyanides have been reported since their identification over 100 years ago.8 Until now, the useful synthetic procedures all required a dehydration reaction8-11 Although the carbylamine reaction involving the dichlorocarbene intermediate is one of the early methods,8 it had not been preparatively useful until the innovation of phase-transfer catalysis (PTC).4 5... 

In addition, there are a few examples of heterogeneous nonaqueous sonochemistry, in both liquid-liquid and liquid-solid systems. Two recent reports have utilized ultrasonic agitation in place of or along with phase transfer catalysis for the preparation of dichlorocarbene from aqueous NaOH/CHCl3 (166), and for N-alkylation of amines with alkyl halides (167). Along the same lines, several papers have appeared in which... 

The ultrasonic preparation of thioamides from amides and phosphorus pentasulfide by Raucher(51) and of dichlorocarbene from chloroform and potassium hydroxide by Regen(52) are some of the more recent examples of nonmetallie applications. We were surprised to find that ultrasound greatly accelerates the reduction of haloaroma-tics by lithium aluminum hydride, permitting the reaction to be... 

A variety of cyclopropane derivatives has been prepared by generating dichlorocarbene in the presence of alknenes. 

Studies by the submitters have indicated that the procedure reported here is the preferred method for the preparation of bicyclo[3.2.1]octan-3-one. It employs readily available, inexpensive reagents, and the overall yield is good. In addition, the method can be used for the synthesis of the difficultly accessible next higher homologues of bicyclo[2.2.2]oct-2-ene as well as for derivatives of norbornene. Bicyclo[3.2.2]nonan-3-one and l-methylbicyclo[3.2.1]octan-3-one have been prepared by a similar route6 in 60% and 47% yields, respectively (based on adduct). However, the preferred procedure for the formation of the dichlorocarbene adduct of bicyclo[2.2.2]oct-2-ene is that of Seyferth using phenyltrichloromethylmercury. Even in this case the overall yield is moderate (37%). 

The generation of dichlorocarbene for addition to olefins has been realized by the use of chloroform and alkali metal alk-oxides4 6 (preferably potassium feri-butoxide), sodium trichloro-acetate,6 butyllithium and bromotrichloromethane,7 and the reaction of an ester of trichloracetic acid with an alkali metal alkoxide.2,8 The latter method, which is here illustrated by the preparation of 2-oxa-7,7-dichloronorcarane, generally gives higher yields of adducts. 

Aminomethylfurans are converted into 3-hydroxypyridines by acid and an oxidizing agent, e.g. (219) —+ (220). 2-Hydroxymethylfurans with chlorine in aqueous methanol give 3-hydroxy-4-pyrones. 3-Hydroxypyridines can conveniently be prepared by reaction of 2-acylfurans with ammonia (Scheme 75). Pyrrole and dichlorocarbene give some 3-chloropyridine (Section 3.3.1.7.1). 

In order to distinguish between the two alternatives, [7-12C]-7,7-dichloronorcarene was prepared by reaction of 1,4-cyclohexadiene with [12C]-dichlorocarbene originating from [12C]-deuteriochloroform ... 

Dihalocyclopropanes are generally prepared by the addition of dihalocarbenes to alkenic substrates. As indicated in the introduction, the first synthesis of a dihalocyclopropane was accomplished by Doering and Hoffmann by the addition of dichlorocarbene, generated from chloroform and potassium r-butoxide (Bu OK), to cyclohexene giving dichloronorcarane (1), as shown in equation (l).s... 

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