Azomethine structure

Since Huisgen et al. first demonstrated the 1,3-dipolar character of pyridine N-imine in 1962,182 the 1,3-dipolar cycloaddition reactions of the heteroaromatic JV-imines have been explored extensively. The reactivity stems from the azomethine structure of the JV-imines.183 The cycloaddition of a variety of activated alkynes and alkenes to the JV-imines yields fused dihydro-pyrazoles and tetrahydropyrazoles, respectively. However, the aromaticity of the heteroaromatic ring is destroyed at this stage, so that such primary cycloadducts usually undergo further reaction to achieve stabilization in various ways as shown in Scheme 4 (i) aromatization, (ii) hydrogen transfer, (iii) rearomatization by rearrangement, and (iv) rearomatization by N—N... 

Table 30.1.2 Pyridine azomethines - structure-activity relationship.

Takata and Hiroi (1964) [153], using a model approach, concluded that cyclization was a fair presumption, whilst a later study of model substances by Brandrup and Peebles (1968) [164] suggested that the azomethine structure was unlikely to be the source of the chromophore. 

Interesting structures can be formed by combinations of ring and side-chain substituents in special relative orientations. As indicated above, structures (28) contain the elements of azomethine or carbonyl ylides, which are 1,3-dipoles. Charge-separated species formed by attachment of an anionic group to an azonia-nitrogen also are 1,3-dipoles pyridine 1-oxide (32) is perhaps the simplest example of these the ylide (33) is another. More complex combinations lead to 1,4-dipoles , for instance the pyrimidine derivative (34), and the cross-conjugated ylide (35). Compounds of this type have been reviewed by Ramsden (80AHCl26)l). 

Equilibration of aziridines via azomethine ylides has been reported for a variety of structures (67JA1753). Most aziridines equilibrated by this method show greater cis stability. An energy barrier has been detected between the two isomeric azomethine ylides (69AG(E)602>. 

The above cycloaddition process consists of two separate [3-1-2] cycloaddition steps and represents a 1,3-2,4 addition of a multiple bond system to a hetero-1,3-diene [7S7]. The structure ot the azomethine imine intermediate has been proved unequivocally by X-ray analysis [195] Ethylene [194], acetylene [/iS2] . many alkyl- and aryl- as well sgemmal dialkyl- and diaryl-substituted alkenes [196,197, 198, 199], dienes [200], and alkynes [182, 201], certain cyclic alkenes [198, 199,... 

Huisgen et al. (1960, 1977 b) found that (i )-4-chlorobenzenediazocyanide reacts with 9-diazofluorene to give the azomethine imine 6.38 in 93 % yield (Scheme 6-28). Huisgen et al. interpret this reaction in terms of the electrophilicity of the diazocyanide at its a-nitrogen atom (not 0 ) and the nucleophilic character of 9-diazofluorene, as shown in the bipolar mesomeric structure 6.37. 

In 1990, Baumeister et al. [127] described the crystal and molecular structure of 4-ethoxy-3 -(4-ethoxyphenyliminomethyl)-4 -(4-methoxy-benzoy-loxy)azobenzene. The molecules have a bifurcated shape. The phenyliminom-ethyl branch is bent markedly from the nearly linear three ring fragment, but is almost coplanar with the azobenzene moiety. They found that the molecular conformation is affected by an intramolecular interaction of the carboxylic and azomethine groups. The crystal packing was described in terms of a sheet structure with interdigitating rows of molecules. 

There have been no reports of complexes of " JV-substituted thiosemicarbazones derived from 2-formylpyridine, but 2-acetylpyridine JV-methyl-thiosemicarbazone, 3a, formed [Fe(3a-H)2]C104 and [Fe(3a-H)2]FeCl4 [117]. The nature of these two species was established by partial elemental analyses, molar conductivities, magnetic moments, electronic, infrared, mass and electron spin resonance spectra. A crystal structure of a related selenosemicarbazone complex confirmed the presence of a distorted octahedral iron(III) cation coordinated by two deprotonated anions so that each ligand is essentially planar and the azomethine nitrogens are trans to each other the pyridyl nitrogen and selenium donors are both cis. 

Corsaro and co-workers studied the reaction of pyridazine, pyrimidine, and pyrazine with benzonitrile oxide and utilized H NMR spectral analysis to determine the exact structure of all the cyclized products obtained from these reactions <1996T6421>, the results of which are outlined in Table 1. The structure of the bis-adduct product 21 of reaction of pyridazine with benzonitrile oxide was determined from the chemical shifts of the 4- and 5-isoxazolinic protons at 3.76 and 4.78 ppm and coupled with the azomethine H at 6.85 ppm and with the 5-oxadiazolinic H at 5.07 ppm, respectively. They determined that the bis-adduct possessed /(-stereochemistry as a result of the large vicinal coupling constant (9.1 Hz). Similarly, the relative stereochemistry of the bis-adducts of the pyrimidine products 22-25 and pyrazine products 26, 27 was determined from the vicinal coupling constants. 

An intramolecular azomethine ylide-mediated cyclization has been used to access the core 5 6 5 angular tricyclic structure of martinellic acid by Snider (Equation 113) <20010L4217>. Reaction of IV-benzylglycine 420 with the aldehyde 419 led to intramolecular cyclization, giving 421 in good yield. 

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). 

The aromatic moieties are possibly substituted benzene or napthaline rings. In azomethine pigments, only one form of metal complex is possible. This is in contrast to azo metal complexes, which may assume either structure 31 or 32 ... 

There is another structure which, although it does not represent a typical azomethine compound, is synthesized from nickel complexes of the anilide of di-imino butyric acid (35). 

Yet another structural principle is represented by metal complex pigments based on isoindolinones. Condensation of amino-iminoisoindolinones (imino-phthalimide) with 2-aminobenzimidazole in a high boiling solvent affords an azomethine (36). This compound reacts with salts of divalent metals, such as Co, Cu, Ni, to yield yellow azomethine metal complex pigments [10] ... 

Commercially available azo and azomethine metal complex pigments cover the spectral range from considerably greenish to reddish yellow and yellowish orange. Compared to their parent structures (the corresponding azo and azomethine compounds), azomethine metal complexes frequently exhibit a distinctly duller shade. Formation of the metal complex often shifts the color of an originally yellow material in the greenish yellow direction. 

Recent developments in this class prefer azomethine complexes as chemical structures rather than azo metal complexes. The list of commercially available types includes Pigment Green 8 and 10, Pigment Yellow 117,129,150,153,177,179, and Pigment Orange 59,65, and 68, as well as P.R.257. 

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