Diazide structure

The problem of the structure of 1,2- and 1,4-quinone diazides was investigated by Le Fevre s group (1949, 1954) by measuring dipole moments. The observed moments in benzene are in the range 2.9 to 5.0 D, compared with calculated values of 1.6 to 4.0 D for the quinone diazide structure and 15.7 and 27.4 D respectively for the 1,2-and 1,4-zwitterionic forms. No attempts were made by Lowe-Ma et al. (1988) to calculate dipole moments for the mesomeric structure 4.4 that they proposed. 

The global minimum of N6has an open-chain diazide structure with C2h symmetry... 

The diazotization products of 2- and 4-aminophenols, -naphthols (etc.), possess a mesomeric (zwitterionic) phenolate-diazonium and quinone-diazide structure. We discussed these structures in the context of aromatic diazotization (Zollinger, 1994 Sect. 2.4) because the synthetic methods used are closely related to those used for aromatic diazonium salts. This is also the case for the diazotization of amino-di-, tri- and tetrazoles, which, in their neutral form, contain a heterocyclic NH group in the )8-position to the amino group. After diazotization, the NH group is very acidic. Following deprotonation the product corresponds to a heterocyclic diazoalkane. Similarly, the diazotization product of 4-(dicyano)methylaniline ((4-amino-phenyl)malonitrile) may lose the CH proton. This compound is, therefore, sometimes called a vinylene homolog of diazomalonitrile (Regitz and Maas, 1986, p. 205). 

In aromatic diazonium compounds containing an ionized hydroxyl group ( —O-) in the 2- or 4-position, it is necessary to consider delocalization of electrons and, therefore, two mesomeric structures (1.7a-1.7b) (see Sec. 4.2). This fact has implications for nomenclature compounds of this type are considered as quinone derivatives following IUPAC Rule C-815.3 (Exception) compounds of this class are called quinone diazides. As a specific compound 1.7a-1.7b is indexed in Chemical Abstracts as 4-diazo-2,5-cyclohexadien-l-one. If reference is made specifically to mesomeric structure 1.7b, however, it is called 4-diazoniophenolate. 

Bis(diazo)-l,2,4,5-cyclohexanetetraone (4.5) may be regarded as a derivative of a double 1,2-quinone diazide. Its X-ray analysis was reported by Ansell (1969). The synthesis, properties, and structure of this interesting compound will be discussed in the forthcoming book on aliphatic diazo compounds (Zollinger, 1995, Secs. 2.3 and 5.2). 

A similar ambiguity concerning structure appears to arise for 1,4-imidoquinone diazides (4.6), which were synthesized many years ago by Dimroth et al. (1917) and by Morgan and Upton (1917), and were reinvestigated by Kazitsyna et al. (1965, 1967, 1968a). Such compounds are obtained by diazotization of 4-aminodiphenylamine and mono-acylated or -formylated 1,4-diaminobenzenes. Under the influence of the... 

In conclusion, with regard to the structure of benzenediazonium compounds with electron donor substituents in the 2- or 4-position, the most recent experimental data, mainly X-ray analyses and 13C and 15N NMR data, are consistent with 4.4 as the dominant mesomeric structure of quinone diazides, as proposed by Lowe-Ma et al. (1988). For benzenediazonium salts with a tertiary amino group in the 4-position the data are consistent with the quinonoid structure 4.20 as the dominant mesomeric form. 

We have to emphasize, however, that this is only a qualitative differentiation of weights of mesomeric structures, and therefore we do not propose that the IUPAC or CA nomenclature (quinone diazides and diazo-cyclohexadien-ones, respectively) should be changed. 

For many decades intramolecular O-coupling was considered not to take place in the diazotization products of 2-aminophenol and its derivatives (for a contrary opinion see, however, Kazitsyna and Klyueva, 1972). The compounds were assumed to be present as one structure only, which can be represented as a mesomer of a phenoxide diazonium zwitterion 6.63 b and a diazocyclohexadienone 6.63 a (see reviews by Kazitsyna et al., 1966 Meier and Zeller, 1977 Ershov et al., 1981). In IUPAC nomenclature 6.63 is called 1,2-quinone diazide, in Chemical Abstracts 6-diazo-2,4-cyclohexadien-one (see Sec. 1.3). More recently, however, Schulz and Schweig (1979, 1984) were able to identify the intramolecular product of O-coupling, i.e., 1,2,3-benzooxadiazole (6.64) after condensation of 6.63 in vacuo at 15 K in the presence of argon (see Sec. 4.2). 

Due to molecular strain, cyclooctyne is a very reactive species. Its reactions with azides proceed rapidly even at room temperature making it a convenient tool for probing structures of unstable azides. Thus, the reaction of cyclooctyne with diazide 1061 carried out in GH2CI2 at room temperature is accomplished within 2h and provides ditriazolyl derivative 1060 in 76% yield. A similar reaction of cyclooctyne with diazide 1062 leads to ditriazolyl derivative 1063 in 90% yield (Scheme 175) <2005T8904>. 

Hydroxybenzenediazonium tetrafluoroborates constitute a special case the meta-isomer has the structure of a true diazonium salt, while the ortho- and para-isomers are in ready equilibrium with the corresponding quinone-diazide dimers which have been isolated as com-... 

To explore further the structural requirements for this unexpected nitrile formation (51 — 52) the reaction of the 1-methyl derivative 56 with sodium azide was examined. In this case the diazido derivative 57 was obtained instead of the nitrile 58. In a control experiment the nitrile 58 was also prepared by methylation of 52 with trimethyl phosphate in the presence of potassium carbonate. 58 reacted in analogy to 52 with sodium azide to furnish the tetrazole 59. Attempted decomposition of the geminal diazide 57 in refluxing DMF failed to give the tetrazole 59 (which is very surprising in view of the easy conversion of 38 to 39) [90LA505],... 

Heavy metal azides have more covalent structures and detonate upon heating or mechanical stress. Lead diazide Pb(N3)2 is used as an initiator for explosives. Like chlorine, azide can act as a ligand in complexes. The complex azido anions are often more stable than binary azide complexes (see Ammonia N-donor Ligands). Dinuclear azide complexes are found with two coordination modes of the azide ion, (56) and (57) depicted in Scheme 20. 

Lead acetate azides, Pb(OAc)4 (N3)n, prepared in situ from lead tetraacetate and azidotrimethylsilane, react with alkenes to yield a variety of products, depending on the structure of the alkene 1,2-diazides. 1,2-acetoxy azides, a-azido ketones, allylic azides, and <5-oxo nitriles (by the oxidative cleavage of cyclohexene rings)97. The diazides and acetoxy azides are formed by preferential syn addition, but the diastereoselectivity (up to 3 1) is far from satisfactory with both acyclic and cyclic alkenes98,99. 

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