Hydroxylamine Cope elimination reaction

Amine oxides 2, which can be prepared by oxidation of amines 1, react upon heating to yield an olefin 3 and a hydroxylamine 4. This reaction is called the Cope elimination reaction,and as a synthetic method is a valuable alternative to the Hofmann degradation reaction of quaternary ammonium salts. 

In addition to being a valuable method for the preparation of olefins, the Cope elimination reaction also gives access to iV,A -disubstituted hydroxylamines. 

The intramolecular nitrone-alkene cycloaddition reaction of monocyclic 2-azetidinone-tethered alkenyl(alkynyl) aldehydes 211, 214, and 216 with Ar-aIkylhydroxylamincs has been developed as an efficient route to prepare carbacepham derivatives 212, 215, and 217, respectively (Scheme 40). Bridged cycloadducts 212 were further transformed into l-amino-3-hydroxy carbacephams 213 by treatment with Zn in aqueous acetic acid at 75 °C. The aziridine carbaldehyde 217 may arise from thermal sigmatropic rearrangement. However, formation of compound 215 should be explained as the result of a formal reverse-Cope elimination reaction of the intermediate ct-hydroxy-hydroxylamine C1999TL5391, 2000TL1647, 2005EJ01680>. 

Cope elimination reaction. Formation of an olefin and a hydroxylamine by pyrolysis of an amine oxide. 

Pyrolysis of the oxide of tertiary amine 1 yields olefin 2 and hydroxylamine 3. This olefination method is known as the Cope elimination reaction.1-3... 

As the name suggests, the reverse Cope elimination reaction involves formation of a tertiary amine oxide from a hydroxylamine and olefin.17,18 For example, reaction of N-methylhydroxylamine (49) with 2,2-diphenyl-4-pentenal (50) in ethanol at room temperature gave amine oxide 51 in 51% yield, together with the expected nitrone 52. It has been suggested the mechanism of the reverse Cope reaction could be a radical chain reaction19,20 however, more recent studies have confirmed the mechanism is analogous to the concerted Cope elimination.17... 

There is a similar commercially available product based on related chemistry. It is a product of a process based on the oxidation of methyl-bis-tallow amine [204933-93-7]. The oxidation product of methyl-bis-tallow amine is a trialkylami-neoxide, a precursor to hydroxylamine stabilization chemistry. The trialkylami-neoxide is converted to a hydroxylamine and a long-chain olefin during the initial melt compounding of the pol5uner by a Cope elimination reaction, as shown below. 

Elimination. Ahphatic amine oxides having an ahphatic hydrogen P to the nitrogen form olefins and diaLkyl hydroxylamines when heated. This reaction is known as the Cope elimination (17)... 

Oxidation of organonitrogen compounds is an important process from both industrial and synthetic viewpoints . N-oxides are obtained by oxidation of tertiary amines (equation 52), which in some cases may undergo further reactions like Cope elimination and Meisenheimer rearrangement . The oxygenation products of secondary amines are generally hydroxylamines, nitroxides and nitrones (equation 53), while oxidation of primary amines usually afforded oxime, nitro, nitroso derivatives and azo and azoxy compounds through coupling, as shown in Scheme 17. Product composition depends on the oxidant, catalyst and reaction conditions employed. 

Cleavage of amine oxides to produce an alkene and a hydroxylamine is called the Cope reaction or Cope elimination (not to be confused with the Cope rearrangement, 18-32). It is an alternative to 17-7 and 17-8. The reaction is usually... 

The pyrolysis of amine oxides is called Cope elimination and typically takes place at 120 °C (Scheme 6.21). The reaction is a syn periplanar elimination in which six electrons move in a five-membered ring according to a concerted, thermally induced mechanism to yield an alkene and a hydroxylamine. 

In contrast to the regioselectivity problems with the Cope elimination, the retro reaction, representing an addition to a double bond, may suffer from insufficient face selectivity, as was noticed with hydroxylamine 580. 

If the reaction between cinnamate 1 and hydroxylamines occurred through a concerted mechanism, the process should take place through a cyclic (five-mem-bered ring) transition state, similar to the ones proposed for [3+2] dipolar cycloadditions or retro-Cope eliminations. The cyclic transition state for the concerted addition of deuterated iV-methylhydroxylamine to ethyl cinnamate 1 is represented in Scheme 8.7 (atoms involved in the cyclization colored blue). As the nitrogen atom and the deuterium approach the C=C bond from the same side, the addition is syn, leading to intermediate 12. A rapid proton shift would give compound 3 which can be either isolated or cyclized in the presence of a Lewis acid to the isoxazolidi-none 4 by intramolecular transesterification. The stereochemistry of the products 3 and 4 is determined during the concerted addition step. 

The products are the corresponding hydroxylamine 4 and the alkene 12 which is a co-unsaturated polymer in case of a polymeric alkoxyamine. In principle, 4 and 12 may also be formed by a concerted intramolecular nonradical Cope-type elimination of the alkoxymine ( ce) (path (b) or reaction (9), Scheme 4.5). 

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