Dediazoniation

This technique has been applied to the synthesis of fluormated dopamine and other compounds of biological significance Fluoroheterocycles such as fluoro-imidazoles [JJ, 36] and fluoropyrazoles [37] can also be prepared by the photo Balz-Schiemann technique (equation 9) Photochemically induced in situ fluoro dediazoniation can also be applied to arenediazonium fluorides in hydrogen fluo nde-pyndine media Thus, o-fluoroanisole is obtained in 73% yield at 20 °C after I8h [dS]... 

A recently discovered variant of the Wallach technique is the silver ion cata lyzed fluorination of aryl diazo sulfides in hydrogen fluonde-pyridine-toluene solvent [57] (equation 12) Electron withdrawing substituents such as acetyl give higher yields of aryl fluoride (71%) than electron donating groups (butyl 39%, methoxy, 2-14%), reductive dediazoniation competes with fluorination... 

Fluoromethylketones are obtained by dediazoniative hydrofluorination with anhydrous hydrogen fluoride [91, 92 93] or Olah s reagent [d] (equation 23)... 

Dediazoniation in the Presence of Carbonyl, Sulfonyl, and Related Compounds 240... 

Photolytic Dediazoniations and their Applications in Synthesis and in Image Technology 277... 

Aromatic diazonium salts are almost as important for reactions in which the diazonio group is lost as molecular nitrogen and in which aryl cations and radicals are the reagent proper (dediazoniation reactions, see Chs. 8 and 10). 

The most comprehensive modern works on the subject are the relevant volumes of Patai s series The Chemistry of Functional Groups, namely the two volumes on diazonium and diazo groups (Patai, 1978), the two volumes on hydrazo, azo, and azoxy groups (Patai, 1975) and the two Supplement C volumes on triple-bonded groups (Patai and Rappoport, 1983). Supplement C contains chapters on arene- and alkene-diazonium ions and on dediazoniation reactions. 

In contrast to the acid, sodium nitrite should not in general be added in excess. Firstly, as far as the ratio of amine to nitrite is concerned, diazotization is practically a quantitative reaction. In consequence, it provides the most important method for determining aromatic amines by titration. Secondly, an excess of nitrous acid exerts a very unfavorable influence on the stability of diazo solutions, as was shown by Gies and Pfeil (1952). Mechanistically the reactions between aromatic diazonium and nitrite ions were investigated more recently by Opgenorth and Rtichardt (1974). They showed that the primary and major reaction is the formation of aryl radicals from the intermediate arenediazonitrite (Ar —N2 —NO2). Details will be discussed in the context of homolytic dediazoniations (Secs. 8.6 and 10.6). 

More recently Gorelik s group determined the structure of 1-phenylsulfonyl-2-pyrazoline-3-diazonium tetrafluoroborate by X-ray crystallography (Gorelik et al., 1989) and calculated (Glukhovtsev et al. 1990) the heats of the dediazoniation reaction of seven cyclic five-membered diazonium ions (including 2.13, R=H) relative to that of the benzenediazonium ion by the MNDO method (see Sec. 8.4). 

Most of the subsequent work on this reagent was concerned with the formation of aryl radicals (see review by Cadogan, 1971). However, 2-terf-butyl-A-nitrosoacet-anilide was found to decompose in benzene to give, instead of 2-tert-butylbiphenyl, as expected for a substitution of benzene by a 2-tert-butylphenyl radical, a mixture of isomeric tert-butylphenyl acetates. A careful reexamination (Cadogan and Hib-bert, 1964) suggested that the ratio of 2- and 3-tert-butylphenyl acetates was consistent with the involvement of 2-tert-butylbenzyne, i.e., the product of an ionic dediazoniation, as an intermediate. This was later confirmed by trapping experiments designed to detect aryne intermediates. 

The reaction of molecular nitrogen with aryl cations, i. e., the reverse reaction of (heterolytic) dediazoniations of arenediazonium ions, is a direct introduction of the... 

In the literature discussing these results, the coincidence of the NN bond lengths in diazonium ions with that in dinitrogen seems always to be regarded with complete satisfaction. In the opinion of the present author this close coincidence is somewhat surprising, firstly because of the fact that in diazonium ions one of the nitrogen atoms is bonded to another atom in addition to the N(2) atom, and secondly because work on dual substituent parameter evaluations of dediazoniation rates of substituted benzenediazonium ions clearly demonstrates that the nx orbitals of the N(l) nitrogen atom overlap with the aromatic 7t-electron system (see Sec. 8.4). 

UV spectra are, however, very useful for the determination of acid-base and ion pair formation equilibria, and for photochemical investigations (e. g., determination of quantum yield in photolytic dediazoniation, Tsunoda and Yamaoka, 1966 fluorescence and phosphorescence at low temperature, Sukigahara and Kikuchi, 1967a). 

The conclusion of Vincent and Random with respect to the dediazoniation and the Na,Np-rearrangement will be discussed in Section 8.4, and their work on the methanediazonium ion in the forthcoming second book (Zollinger, 1995, Sec. 5.3). 

The experimental work of the groups of Swain and Zollinger on the dediazoniation mechanism of arenediazonium ions, which started in 1975, provided good evidence for the existence of aryl cations as steady state intermediates (see Sec. 8.3). These results also initiated theoretical work on aryl cations, in part combined with further calculations on the structure and reactivity of arenediazonium ions. Publications that contain data on arenediazonium ions and aryl cations will therefore be discussed in the chapter on dediazoniation reactions (Sec. 8.4). In the rest of this section we will concentrate on investigations that are concerned with the geometries and electron densities of diazonium ions but not, or only marginally, with energetics of the dediazoniation reaction. 

The rapid formation of the (Z)-diazoate is followed by the slower (Z/J )-isomeri-zation of the diazoate (see Scheme 5-14, reaction 5). Some representative examples are given in Table 5-2. Both reactions are first-order with regard to the diazonium ion, and the first reaction is also first-order in [OH-], i.e., second-order overall. So as to make the rate constants k and k5 directly comparable, we calculated half-lives for reactions with [ArNj ]0 = 0.01 m carried out at pH = 9.00 and 25 °C. The isomerization rate of the unsubstituted benzenediazonium ion cannot be measured at room temperature due to the predominance of decomposition (homolytic dediazoniations) even at low temperature. Nevertheless, it can be concluded that the half-lives for (Z/ )-isomerizations are at least five powers of ten greater than those for the formation of the (Z)-diazohydroxide (reaction 1) for unsubstituted and most substituted benzenediazonium ions (see bottom row of Table 5-2). Only for diazonium ions with strong -M type substituents (e.g., N02, CN) in the 2- or 4-position is the ratio r1/2 (5)/t1/2 (1) in the range 6 x 104 to 250 x 104 (Table 5-2). 

Semiquantitatively, the reaction of an aromatic diazonium ion with the methoxide ion occurs in three phases. The first is the extremely rapid formation of the (Z)-diazo methyl ether. This is followed by a second, partitioning, phase which in the case of the 4-nitrobenzenediazonium ion at 30 °C is completed in 60 s (Boyle et al., 1971). During this phase, some of the (Z)-diazo ether decomposes to form dediazoniation products (mainly nitrobenzene via the hydro-de-diazoniation reaction) and the rest is converted into the (Zi)-diazo ether. 

Broxton and Roper measured the rate of dissociation (A 3) of the (ii)-diazo ether, A 2, and the rate of the protection reaction (A p), i.e., the transformation of the (Z)-into the (ii)-ether ( protection because the diazo ether is protected against dediazoniation almost completely if present as the ( >isomer). Rate constants kx and k are known from Ritchie and Virtanen s work (1972). The results demonstrate firstly that the initial reaction of the diazonium ion takes place in such a way that almost exclusively the (Z)-ether is formed directly (ki/k3 = 120). The protection rate constant kp is a simple function of the intrinsic rate constants as shown in Scheme 6-4. 

As expected, the addition of arenediazonium ions to thiophenols does not involve the thiophenol molecule, but rather the thiophenoxide ion (Price and Tsunawaki, 1963). Dediazoniation with the formation of a diarylsulfide (6.16) is competitive with the formation of the diazo thioether 6.15 (Scheme 6-9 van Zwet et al., 1970). Whereas the early investigators detected only one isomer, (Z)- and (ii)-forms were... 

Recently Noble s group (Haub et al., 1992) showed that sulfidomolybdenum dimer anion complexes react with arenediazonium ions and form complexes (Mo)2S — N2 — Ar. Synthesis and (homolytic) dediazoniation reflect characteristics of arene-diazosulfide anions (see Zollinger, 1995, Sec. 10.1). 

The reaction of azide ions with aliphatic diazo compounds was investigated by Kirmse et al. (1979 for a discussion see Zollinger, 1995, Sec. 6.1). Here we mention only that cyclopropanediazonium ions react similarly to the aromatic diazonium ions, i.e., by TV-coupling to 1-cyclopropylpentazene and dediazoniation to cyclopropyl azide. In about 60% of the 1-cyclopropylpentazene the cyclopropyl azide is formed directly by dediazoniation of the original diazonio group, while in 40% the route is via the cyclopropylpentazole. 

DSP treatments allow one to separate the field and mesomeric effects of substituents on chemical reactivities and physical properties (electronic and NMR spectra, etc.) of organic compounds. In Section 8.3 we will discuss heterolytic dediazoniation of substituted benzenediazonium ions. For this series of reactions the classical Hammett equation completely fails to give useful results (see Fig. 8-1), but the DSP treatment yields a good and mechanistically very meaningful correlation. 

The term dediazoniation was introduced by Bunnett as early as 1954. It is now included in the IUPAC system of naming transformations in organic chemistry (IUPAC, 1989 a). 

Dediazoniation refers to all those reactions of diazo and diazonium compounds in which an N2 molecule is one of the products. The designation of the entering group precedes the term dediazoniation, e. g., azido-de-diazoniation for the substitution of the diazonio group by an azido group, or aryl-de-diazoniation for a Gomberg-Bachmann reaction. The IUPAC system says nothing about the mechanism of a reaction (see Sec. 1.2). For example, the first of the two dediazoniations mentioned is a heterolytic substitution, whereas the second is a homolytic substitution. 

In this chapter we will discuss only the dediazoniation of arenediazonium ions (Group a). The dediazoniation of alkene- and alkanediazonium ions and of diazoalkanes (Groups b, c, and d) will be treated in the second book on diazo chemistry (Zollinger, 1995, Chs. 7-9). 

Dediazoniations of azides and azo extrusions are discussed in this book only occasionally. 

In this chapter the major emphasis is on the mechanistic aspects of dediazoniations because they are the basis for understanding the relative instability of diazo and diazonium compounds, and because a knowledge of these is helpful for optimizing synthetic applications of such compounds. Syntheses based on dediazoniation of arenediazonium salts are the subject of Chapter 10. 

The dediazoniation of aromatic diazonium ions has been found to involve a variety of mechanisms. Three typical examples should suffice to show that seemingly slight modifications in the reaction system can lead to entirely different reaction products these suggest fundamentally different dediazoniation mechanisms ... 

Dediazoniation of three o-substituted benzenediazonium salts in pyridinium poly(hydrogen fluoride) yields different products depending on the substituent, as Olah and Welch (1975) have found. The 2-methyl derivative gives 2-fluoro-toluene. With the 2-nitrobenzenediazonium ion the main product is 3-nitrofluoro-benzene, the 2-isomer being formed only in small quantities. Finally, the 2-tri-fluoromethyl derivative yields all three isomeric trifluoromethylfluorobenzenes. 

The first two examples clearly indicate that slight modifications (02 to N2 atmosphere, unsubstituted to 4-nitrosubstituted benzenediazonium ion) can change a heterolytic reaction into a homolytic one. The changeover from heterolytic to homolytic dediazoniation will be discussed in more detail in Section 8.7 of this chapter. The ratio of products in the third example suggests, as indicated in Scheme 8-2, that a DN + AN substitution (A), a reaction via an aryne (B), a o-substitution of the type described by Kovacic and Gormisk (1966) (D), and a... 

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