Schmidt type reaction

Further examples of the Schmidt reaction and of Schmidt type reactions are collected in Scheme 11/16. 

A variation of the Schmidt type reaction is the rearrangement of an azidocyc-loalkane, which is formed from the addition of hydrazoic acid to an cycloalkene. This reaction was used in the synthesis of muscopyridine (II/U4), a base isolated from the perfume gland of the musk deer [85]. In this context the reaction of II/115 as a model compound under the conditions of the Schmidt reaction gave a mixture of two compounds which after dehydrogenation yielded 11/116 and 11/117. The mechanism can be explained in terms of the migration of different bonds in the precursor. 

Reaction of RN, with ketones.2 TiCl4 (2.5 equiv.) can effect a Schmidt type reaction of alkyl azides with cyclic ketones to afford N-alkyllactams. An aldol-typc reaction can also occur bul can be suppressed by use of excess (2 equiv.) of the alkyl azide. Highest yields are obtained with cyclohcxancs, but ring expansion products can be obtained in 20-25% yield from cyclopcntanonc and cyclobutanoncs. 

The reactions of HN3 with cyclic alcohols to yield mixtures of ketones, amines, and products with an enlarged ring are catalyzed by H2SO4 [1]. Tertiary alcohols are converted to azides in the presence of acid [12] or TiCU [13]. Aldehydes and ketones with HN3 undergo a Schmidt-type reaction by liberating N2 and inserting NH In the presence of H or Lewis acids [14]. Ketones yield secondary amides and, in the case of cyclic ketones, lactames. Aldehydes are converted to nitriles or N-formylamines. Tetrazole derivatives result with excess HN3 [1, 15]. However, a-azido ethers are obtained from aldehydes and HN3 in the presence of alcohols by catalysis of TiC [16]. Carboxylic acids and anhydrides form amines, N2, and CO2 in Schmidt reactions with HN3. Intermediates are carbamic acids which form by insertion of NH into the R-COOH bond [1, 14]. High yields result for acids of arenes [17]. 

En gros, the N insertion reactions can be subdivided into a Beckmann type and a Schmidt-type rearrangement part. Furthermore, some photochemical rearrangements of chiral oxaziridines are known to generate a range of optically active lactams. 

Miscellaneous reactions. Pyrrolo-benzazepinedione 50 has been synthesized by a Schmidt type rearrangement and ring enlargement of diketone 49... 

The formation of ry-nitrostyrenes (illustrated in Expt 6.136) by reaction of nitroalkanes with aromatic aldehydes in the presence of aqueous alkali may be classified with reactions of the Claisen-Schmidt type. 

The participation of nitrilium salts has also been postulated42 in the Schmidt reaction and in some Beckmann rearrangements when concentrated sulfuric acid is employed. Hill43 has demonstrated recently that some Beckmann rearrangements carried out in a concentrated sulfuric acid medium are Ritter-type reactions in which the nitrile formed in situ from the oxime combines with a carbonium ion to yield a nitrilium salt, which, when diluted with water, leads to the N-alkylamide. 

Traditionally, relative stabilities of carbocations have been derived from the comparison of the rates of solvolysis reactions following the SN1 mechanism, for which the designation Dm + An has recently been proposed [36], The comparison of solvolytic rate constants for substrates of a large structural variety is hampered by the fact that the published solvolysis rates refer to different solvents, different temperatures, and precursors with different leaving groups. Dau-Schmidt has, therefore, converted solvolysis rates of a manifold of alkyl chlorides and bromides to standard conditions, i.e., soiv of RC1 in 100% EtOH at 25° C (Scheme 6) [37]. Although from a theoretical point of view, ethanol is not an ideal solvent for observing unassisted SN 1-type reactions (nucleophilic solvent participation), it has been selected as the reference solvent because most available experimental data have been collected in solvents of comparable nucleophilicity, a fact which made conversions to 100% ethanol relatively unproblematic [38],... 

The Claisen-Schmidt Reaction. When aromatic aldehydes are treated with aliphatic ketones in the presence of base, three reactions might be expected a Cannizzaro reaction of the aromatic aldehyde an aldol-type reaction of the ketone or a crossed aldol reaction between the ketone and the aromatic aldehyde. In either of the last two possibilities dehydration might also occur. Undoubtedly all these reactions will take place in strong base, but by employing about 10 per cent aqueous sodium hydroxide, good yields are often obtained of j3-unsaturated carbonyl conipounds derived from a crossed aldol reaction between the aldehyde and the ketone. This reaction, generally called a Claisen-Schmidt reaction, can be illustrated by the synthesis of benzalacetophenone.16... 

A variety of spiro-tetrahydroisoquinoline-piperidines have been synthesized by established routes. The compounds and methods include (30) by a Pictet-Spengler-type reaction, (31) by cyclization of an N-3,4-dimethoxybenzylglycine nitrile derivative, and (32) via Schmidt rearrangement of a 3-spiro-indan-l-one derivative. ... 

The aldol reaction (aldol condensation) is one of the fundamental reactions of organic chemistry because it leads to the formation of a new carbon-carbon bond (see Experiment [20] for a very similar example of the Qaisen-Schmidt type of aldol reaction). In this version, the condensation of 4-nitrobenzaldehyde (an aldehyde without an a-hydrogen atom) with acetophenone (a ketone) gives frans-4-nitrochalcone.The aldol condensation of the unsubstituted aromatic aldehyde, benzaldehyde with acetophenone, yields frans-l,3-diphenyl-2-propenone (PhCH CHCOPh), which has the common name, chalcone.Thus, the substituted derivatives of this system are known collectively as chalcones. 

The aldol reaction and other venerable processes such as the Knoevenagel, Claisen-Schmidt, Perkin, Darzen, Tollens and Wittig reactions are base-catalyzed (sometimes acid-catalyzed too) reactions between an active methylene compound and an aldehyde or a ketone. In the last decade the term aldol-type reaction has been used to indicate that the initial addition step is mechanistically the same for all these reactions. 

With alkyl aryl ketones, it is the aryl group that generally migrates to the nitrogen, except when the alkyl group is bulky. The reaction has been applied to a few aldehydes, but rarely. With aldehydes the product is usually the nitrile (16-21). Even with ketones, conversion to the nitrile is often a side reaction, especially with the type of ketone that gives 17-31. A useful variation of the Schmidt reaction treats a cyclic ketone with an alkyl azide (RN3) in the presence of TiCU, generating a... 

Concerning the reaction pathway, two routes have been proposed the sequence of total oxidation of methane, followed by reforming of the unconverted methane with CO2 and H2O (designated as indirect scheme), and the direct partial oxidation of methane to synthesis gas without the experience of CO2 and H2O as reaction intermediates. The results obtained by Schmidt and his co-workers [4, 5] indicate that the direct reaction scheme may be followed in a monolith reactor when an extremely short contact time is employed at temperatures in the neighborhood of 1000°C. However, the majority of previous studies over numerous types of catalysts show that the partial oxidation of methane follows the indirect reaction scheme, which is supported by the observation that a sharp temperature spike occurs near the entrance of the catalyst bed, and that essentially zero CO and H2 selectivity is obtained at low methane conversions (<25%) where oxygen is not fully consumed [2, 3]. A major problem encountered... 

Nitrones derived from 2-azabicyclo[5.3.0]decane give quinolizidine compounds by photochemical Beckmann rearrangement which implies simultaneous ring expansion and ring contraction reactions. Intramolecular Schmidt reactions in 2(4-azidobutyl)-cyclopentanones also give quinolizidinone derivatives by ring expansion. Examples of both types of reactions are given in Sections 12.01.11.1 and 12.01.11.3, respectively. 

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