Diazoalkanes synthesis

Bordoni, S., Busetto, L., Cassani, M.C., Albano, V.G. and Sabatino, P. (1994) Reactions of [Au(C6F5)(SC4Hs)] with diazoalkanes. Synthesis and molecular structures of [cyclic] [Au(C6F5)(Ph2C NN CPh2)[. Inorganica Chimica Acta, 222 (1-2), 267-273. 

The preparation of iV-nitroso-/5-alkylaminoisobutyl ketones is of particular interest as a method for preparing the intermediates for the diazoalkane synthesis. The preparation of these compounds is based on the addition of a primary amine to mesityl oxide to give a secondary amino ketone which is then nitrosated (see Volume I, Chapter 15, Section 2A,g). This preparation uses an... 

The first scientist who carried out a diazo transfer reaction was Dimroth (1910). The process was rediscovered by Curtius and Klavehn (1926) — more than 40 years after Curtius established the first diazoalkane synthesis, and two years before he died (see Sects. 1.1 and 2.3) — and again by Doering and DePuy in 1953. Their synthesis of diazocyclopentadiene from cyclopentadienyllithium and 4-toluenesulfonyl azide (tosyl azide, see Zollinger, 1994, page 33, Scheme 2-31) has, however, only been occasionally used for other diazo transfer reactions (e.g., by Farnum and Yates, 1960 ... 

Some qualitative data prove these copolymers to be random. It is necessary to incorporate 20mol-% of prattene-1 into the copolymer to obtain amorphous products 149) copolymers with a lower pentene-1 contort exhibit low crystallinity 148,150). The melting points of model copolymers obtained 1 diazoalkane synthesis 110) demonstrate a sharp fall with increasing branch content from 113.7° C for 2.0% to 89.0° C for 4.2 and 64° C for 6.4%. 

PFAU - PLATTNER Cyclopropane synthesis DIazoalkane insertion Into olelins wtth lormation of cyclopropanes or ring enlargement ol aromatics to cydoheptatnenes see also lormation ol pyrazoHnes (von Pechman). 

Reactions offluorinated dipoles. In recent years, much effort has been devoted to the preparation of tnfluoromethyl-substituted 1,3-dipoles with the goal of using them to introduce trifluoromethyl groups into five-membered nng heterocycles Fluorinated diazoalkanes were the first such 1,3-dipoles to be prepared and used in synthesis A number of reports of cycloadditions of mono- and bis(tnfluo-romethyl)diazomethane appeared prior to 1972 [9] Other types of fluonne-substi-tuted 1,3-dipoles were virtually unknown until only recently However, largely because of the efforts of Tanaka s group, a broad knowledge of the chemistry of tnfluoromethyl-substituted nitrile oxides, nitnle imines, nitnle ylides, and nitrones has been accumulated recently... 

Photo-de-diazoniation has found relatively little application in organic synthesis, as is clearly evident from the annual Specialist Periodical Reports on Photochemistry published by the Royal Society of Chemistry. Since the beginning of these reports (1970) they have contained a section on the elimination of nitrogen from diazo compounds, written since 1973 by Reid (1990). In the 1980s (including 1990), at least 90% of each report is concerned with dediazoniations of diazoalkanes and non-quinon-oid diazo ketones, the rest being mainly related to quinone diazides and only occasionally to arenediazonium salts. 

As noted in the preceding section, one of the most general methods of synthesis of esters is by reaction of alcohols with an acyl chloride or other activated carboxylic acid derivative. Section 3.2.5 dealt with two other important methods, namely, reactions with diazoalkanes and reactions of carboxylate salts with alkyl halides or sulfonate esters. There is also the acid-catalyzed reaction of carboxylic acids with alcohols, which is called the Fischer esterification. 

Carbenes from Diazo Compounds. Decomposition of diazo compounds to form carbenes is a quite general reaction that is applicable to diazomethane and other diazoalkanes, diazoalkenes, and diazo compounds with aryl and acyl substituents. The main restrictions on this method are the limitations on synthesis and limited stability of the diazo compounds. The smaller diazoalkanes are toxic and potentially explosive, and they are usually prepared immediately before use. The most general synthetic routes involve base-catalyzed decomposition of V-nitroso derivatives of amides, ureas, or sulfonamides, as illustrated by several reactions used for the preparation of diazomethane. 

The synthesis of longifolene in Scheme 13.30 commenced with a Birch reduction and tandem alkylation of methyl 2-methoxybenzoate (see Section 5.6.1.2). Step C is an intramolecular cycloaddition of a diazoalkane that is generated from an aziridinoimine intermediate. 

Other synthetic approaches have been explored for binding an alkylidene functionality to a metalla-calix[4]arene. Among them, the reaction of diazoalkanes with coordinatively unsaturated metalla-calix[4]arenes deserves particular mention. The synthesis of an unusual high-spin (5.2 BM at 292 K) iron(II)-carbene, 192, is displayed in Scheme 39,13 and its structure is shown in Fig. 22. 

The 1,3-dipolar cycloaddition reactions to unsaturated carbon-carbon bonds have been known for quite some time and have become an important part of strategies for organic synthesis of many compounds (Smith and March, 2007). The 1,3-dipolar compounds that participate in this reaction include many of those that can be drawn having charged resonance hybrid structures, such as azides, diazoalkanes, nitriles, azomethine ylides, and aziridines, among others. The heterocyclic ring structures formed as the result of this reaction typically are triazoline, triazole, or pyrrolidine derivatives. In all cases, the product is a 5-membered heterocycle that contains components of both reactants and occurs with a reduction in the total bond unsaturation. In addition, this type of cycloaddition reaction can be done using carbon-carbon double bonds or triple bonds (alkynes). 

Moffett and coworkers203 reported the synthesis of several 4-/3-D-ribofuranosylpyrazoles, such as 284(a-c), by 1,3-dipolar cycloaddition of diazoalkanes to the alkenic C-glycosyl compound 283, followed by dehydrogenation of the resulting pyrazolines. In view of the known biological activities of several nucleosides containing the... 

The ruthenium carbene complexes 1 discussed in the previous chapter have set the standards in the field of olefin metathesis and are widely appreciated tools for advanced organic synthesis [3]. A serious drawback, however, relates to the preparation of these compounds requiring either 3,3-diphenylcyclopropene or diazoalkanes, i.e. reagents which are rather difficult to make and/or fairly hazardous if used on a large scale [60]. Therefore, a need for metathesis catalysts persists that exhibit essentially the same activity and application profile as 1 but are significantly easier to make. 

The method is of general applicability7 for the synthesis of olefins. Other sulfonyl chlorides, RCH2SO2CI, have been used where R = H, C2H5, CeHs, and C6H5CH2 other diazoalkanes that have been used are diazoethane and l-diazo-2-methyl-propane. In all cases the olefins form without double-bond migration. 

One of the most fascinating transformations of free carbenes, generated for instance by photolysis of diazoalkanes or by a-elimination, is their insertion into aliphatic C-H bonds. This ability of carbenes is not only of theoretical interest, but also a unique tool for the synthesis of highly strained compounds such as, e.g., bicyclo[l. 1.0]butanes. 

Reaction of diazo compounds with a variety of transition metal compounds leads to evolution of nitrogen and formation of products of the same general type as those formed by thermal and photochemical decomposition of diazoalkanes. These transition metal-catalyzed reactions in general appear to involve carbenoid intermediates in which the carbene becomes bound to the metal.83 The metals which have been used most frequently in synthesis are copper and rhodium. 

Numerous methods to prepare individual classes of aliphatic diazo compounds have been extensively developed. The major strategies for their synthesis involve the alkaline cleavage of N-alkyl-N-nitroso-ureas, -carboxamides and -sulfonamides, dehydrogenation of hydrazones, as well as diazo group transfer from sulfonyl and related azides to active methylene compounds, and electrophilic diazoalkane substitution reactions. These synthetic methods have been comprehensively reviewed (15,16). Useful information on the preparation of selected diazo compounds can be found elsewhere (6,17). 

In the context of stereoselective organic synthesis, diastereofacial-selective cycloadditions of diazoalkanes and diazoacetates with functionalized alkenes has attracted some attention. 3,4-Disubstituted cyclobutenes were studied as dipolar-ophiles by the groups of Gandolfi and co-workers (113) and Martin and co-workers (114). The transition state structures of the cycloaddition of diazomethane with cis-3,4-dimethylcyclobutene was investigated theoretically by DPT methods (113a). 

Ketenes rarely produce [3+ 2]-cycloaddition products with diazo compounds. The reaction possibilities are complex, and nitrogen-free products are often obtained (5). Formation of a cyclopropanone represents one possibihty. Along these lines, the synthesis of (Z)-2,3-bis(trialkylsilyl)cyclopropanones and (Z)-2-trialkylsilyl-3-(triethylgermyl)cyclopropanones from diazo(trialkylsilyl)methanes and appropriate silyl- or germylketenes has been reported (256,257). It was found that subsequent reaction of the cyclopropanone with the diazoalkane was not a problem, in contrast to the reaction of diazomethane with the same ketenes. The high cycloaddition reactivity of diazomethylenephosphoranes also extends to heterocumulenes. The compound R2P(C1)=C=N2 (R = N(/-Pr)2) reacts with CS2, PhNCO and PhNCS to give the corresponding 1,2,3-triazole derivative (60). 

In a novel total synthesis of the tricyclic sesquiterpene (—)-longifolene, an intramolecular diazoalkane cycloaddition to a cyclohexadienone ring followed by thermal ring contraction of the resulting pyrazoline gave the tricychc vinylcyclo-propane 261 and this constitutes the key steps in this synthesis (314) (Scheme 8.63). The interesting features of this sequence are the separation of dipole and dipolarophile by five atoms and the formation of a seven-membered ring in the cycloaddition step. 

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