Benzenediazonium salt

Aromatic acyl halides and sulfonyl halides undergo oxidative addition, followed by facile elimination of CO and SO2 to form arylpalladium complexes. Benzenediazonium salts are the most reactive source of arylpalladium complexes. 

The ratio between the isomers obtained in coupling with 1,3- and 1,5-naphtholsulfonic acids depends on the reactivity of the diazo component. Energetic ones, such as the 2,4-dinitrobenzenediazonium compound, essentially couple only with l-naphthol-3-sulfonic acid [3771-14-0] in the para position, but 4-chloro-benzenediazonium salt (a weaker diazo) attacks the ortho position. Both isomers result when mononitrobenzenediazonium compounds are used. The tendency to couple para is greater in l-naphthol-5-sulfonic acid [117-59-9] C QHgO S (21). For the combination of... 

Diazo coupling occurs very readily between pyrroles and indoles and benzenediazonium salts. Reaction is much more rapid in alkaline solution when the species undergoing reaction... 

Benzenediazonium fluoroborate, 2-carboxy-xanthone synthesis from, 3, 838 Benzenediazonium ions phenyl azide formation from, 5, 839 Benzenediazonium salts, o-(imidazol-l-yl)-intramolecular diazo coupling, 5, 404 Benzene-1,2-disulfonimides N-substituted reactions, 6, 930 Benzene episulfide formation, 7, 577 Benzeneimine... 

A careful study of the phenylation of quinoxaline with benzoyl peroxide, various benzenediazonium salts, and A -nitrosoacetanilide indicates that the 2-position is most reactive to phenyl radicals and that the 5-position is more reactive than the 6. The yields of 2-, 5-, and 6-phenylquinoxaline are in the ratio of 40 10 1, Benzoyl peroxide and A—nitrosoacetanilide are the most effective phenylating reagents. 

Much earlier information on the structure of diazonium ions than that derived from X-ray analyses (but still useful today) was obtained by infrared spectroscopy. The pioneers in the application of this technique to diazonium and diazo compounds were Le Fevre and his school, who provided the first IR evidence for the triple bonds by identifying the characteristic stretching vibration band at 2260 cm-1 (Aroney et al., 1955 see also Whetsel et al., 1956). Its frequency lies between the Raman frequency of dinitrogen (2330 cm-1, Schrotter, 1970) and the stretching vibration frequency of the C = N group in benzonitrile (2255 cm-1, Aroney et al., 1955). In substituted benzenediazonium salts the frequency of the NN stretching vibration follows Hammett op relationships. Electron donor substituents reduce the frequency, whereas acceptor substituents increase it. The 4-dimethylamino group, for example, shifts it by 103 cm-1 to 2177 cm-1 (Nuttall et al., 1961). This result supports the hypothesis that... 

Ultraviolet spectra of diazonium salt solutions were recorded for the first time by Hantzsch and Lifschitz as early as 1912. However, electron spectra did not provide significant information on the structure of diazonium ions, either at that time or later. For example, Anderson and coworkers (Anderson and Steedly, 1954 Anderson and Manning, 1955), compared spectra of 4-amino-benzenediazonium salts with those of diphenylquinomethane (4.18). Their conclusion that the structures of these compounds are analogous is basically correct, but the arguments given by Anderson can easily be refuted, as shown by Sorriso (1978, p. 102). 

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. 

This and related syntheses involving diazonium salts were reviewed by Biffin et al. (1971, p. 148). The hypothesis that the triazene occurs as intermediate in Scheme 6-14 has been corroborated by the experiments of Clusius and Hiirzeler (1954) using benzenediazonium salts labeled with 15N at the a- or Impositions. Ammonia adds exclusively at the p-nitrogen no rearrangements were observed. 

The fundamental understanding of the diazonio group in arenediazonium salts, and of its reactivity, electronic structure, and influence on the reactivity of other substituents attached to the arenediazonium system depends mainly on the application of quantitative structure-reactivity relationships to kinetic and equilibrium measurements. These were made with a series of 3- and 4-substituted benzenediazonium salts on the basis of the Hammett equation (Scheme 7-1). We need to discuss the mechanism of addition of a nucleophile to the P-nitrogen atom of an arenediazonium ion, and to answer the question, raised several times in Chapters 5 and 6, why the ratio of (Z)- to ( -additions is so different — from almost 100 1 to 1 100 — depending on the type of nucleophile involved and on the reaction conditions. However, before we do that in Section 7.4, it is necessary to give a short general review of the Hammett equation and to discuss the substituent constants of the diazonio group. 

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 formation of arynes (8.26) as metastable intermediates in aromatic dediazo-niations was postulated by Stiles and Miller (1960) for the case of the 2-carboxy-benzenediazonium zwitterion (8.25) and by Cadogan and Hibbert (1964) for unsubstituted benzenediazonium salts. ... 

Szele and Zollinger (1978 b) have found that homolytic dediazoniation is favored by an increase in the nucleophilicity of the solvent and by an increase in the elec-trophilicity of the P-nitrogen atom of the arenediazonium ion. In Table 8-2 are listed the products of dediazoniation in various solvents that have been investigated in detail. Products obtained from heterolytic and homolytic intermediates are denoted by C (cationic) and R (radical) respectively for three typical substituted benzenediazonium salts and the unsubstituted salt. A borderline case is dediazoniation in DMSO, where the 4-nitrobenzenediazonium ion follows a homolytic mechanism, but the benzenediazonium ion decomposes heterolytically, as shown by product analyses by Kuokkanen (1989) the homolytic process has an activation volume AF = + (6.4 0.4) xlO-3 m-1, whereas for the heterolytic reaction AF = +(10.4 0.4) x 10 3 m-1. Both values are similar to the corresponding activation volumes found earlier in methanol (Kuokkanen, 1984) and in water (Ishida et al., 1970). 

Table 8-2. Main products of dediazoniation of substituted benzenediazonium salts in solvents of different nucleophilicity.

A comparison of the products from the four benzenediazonium salts makes it clear that an increase in the electrophilicity of the diazonium ion favors homolytic dediazoniation in borderline solvents. As discussed in Section 8.6, increased electrophilicity is accompanied by an increase in the reduction potential (Ei/2), which is a measure of the tendency to add an electron and form an arenediazenyl radical (Ar-N ). 

With Pd(dba)2 in acetone/dichloromethane (1 1) and ethene (6-8 atm), styrene is formed from benzenediazonium tetrafluoroborate in 51% yield with seven substituted benzenediazonium salts the yields were 62-75%, but very small yields were obtained with the 2,4,6-trimethyl and the 2- and 4-nitro derivatives (Kikukawa et al., 1979). The two nitrodiazonium salts are good substrates in the Meerwein reaction... 

Table 10-9. Yields in homolytic dediazoniation reactions of 2-(2 -propenyl)benzenediazonium salts (10.55, Z = 0, 7i = l, R=H or CH3) and the related diazonium salt 10.59.

Ambroz and Kemp (1979 a, 1982 a, b) photolyzed benzenediazonium salts with donor substituents in the 4-position (2,5-di- -butoxy-4-morpholine-, 2,5-diethoxy-4-H-butylthio-, and 2,4,5-trimethoxy-benzenediazonium hexafluorophosphate in LiCl - H20 - acetone matrices at low temperatures, 77-130 K). Under these conditions the aryl cation formed is sufficiently stable to be identified spectroscopically. It is a triplet, a result that is consistent with earlier ab initio calculations by Dill et al. (1977), and with earlier observations by Lee et al. (1961), also at low temperature (77 K). 

Kuokkanen (1986, 1987 a, 1991) supported the proposal of Nakazumi et al. (1983) based on kinetic and spectrophotometric comparisons of arenediazonium salt solutions in the presence of 18-crown-6 and pentaglyme. He also extended the systematic work on complex formation of benzenediazonium salts, substituted in the 2-position, and in the presence of 15-crown-5 (Kuokkanen, 1990 Kuokkanen et al, 1991). He discovered a useful way to differentiate between the two types of complexes in Scheme 11-2. Increasing the relative concentration of the host compound shifts the ultraviolet absorption band of both types of complex hypsochromically, whereas the NN stretching frequencies are significantly increased only in the case of insertion complexes. ... 

In Brown s classification a diazonium ion is a reagent of very low reactivity and correspondingly high substrate selectivity and regioselectivity. This follows from the fact that benzenediazonium salts do not normally react with weakly nucleophilic benzene derivatives such as toluene. More reactive heteroaromatic diazonium ions such as substituted imidazole-2-diazonium ions will even react with benzene (see Sec. 12.5). 

A quantitative study of the azo coupling reactions of heterocyclic diazo compounds was made by Sawaguchi et al. (1971), who measured the coupling rates of seventeen heterocyclic diazonium ions with R-acid (2-naphthol-3,6-disulfonic acid) and compared them with those of the benzenediazonium ion with the same coupling component. All the heterocyclic diazonium ions investigated react faster with R-acid than does the benzenediazonium salt. More recently, Diener and Zollinger (1986) confirmed Sawaguchi s results and interpreted them in more detail. 

The occurrence of arenediazo alkyl and aryl ethers as intermediates has been discussed since 1870, when Kekule and Hidegh postulated that in the azo coupling reaction of benzenediazonium salts with phenol, 4-phenylazophenol is formed via the diazo phenyl ether. The analogous problem for diazo methyl ethers was first discussed by von Euler (1903). 

In the early 1960s it was shown that the anion B10H 0 " acts as a reactive substrate in electrophilic substitutions such as halogenations, alkylations, nitrosations, and deuterations (see Housecroft, 1990, Figs. 7.3.1 and 7.3.2). Therefore Hawthorne and Olsen (1964, 1965) investigated the reactivity of this anion with a series of unsubstituted and substituted benzenediazonium salts. In aqueous solution yellow and... 

The quite negative reduction potentials of spin traps (Table 2) make them less amenable to participation in the radical anion mechanism, as first established in the cathodic reduction of benzenediazonium salts at a controlled potential in the presence of PBN (Bard et al., 1974). In fact, the lower cathodic limit of the spin trapping method is set not by the nitrone but by the spin adduct formed. 

Occasionally, the successful application of the Marcus expressions (5.35) and (5.37) to a reaction can support its designation as outer-sphere. The reduction of a series of substituted benzenediazonium salts by Fe(CN)5 and (Me5cp)2pe conforms to the simple Marcus expression and represents supporting evidence for the formulation of these reactions as outer sphere (or non-bonded electron transfer in organic systems)... 

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