Diazonium salts functional derivatives

Nucleophilic processes that generate chloroindoles are largely confined to the displacements of oxy functions and Sandmeyer reactions of diazo-nium salts [81 H( 15)547]. A low yield of 2-chloroindole was obtained by a reaction sequence that involved treatment of oxindole with phosphoryl chloride, and then treatment of the Vilsmeier salt with sodium bicarbonate [66JOC2627 86H(24)2879]. It is, however, much better to prepare this compound from 2-lithioindole (92JOC2495). With phosphoryl chloride and dimethylformamide ethyl l-hydroxyindole-2-carboxylate failed to give the expected 3-formyl derivative. Instead there was a 50% yield of the 3-chloro derivative (84CPB3678). Diazonium salts have been used as precursors in... 

In the isomer (156) (and its 4-amino and 4-oxo derivatives) 3-bromination also occurred [82CHE753 87AHC(41)320]. The 4-bromo compound was made in 40% yield from the diazonium salt (82CHE753), whereas a 3-oxo function was replaced by chlorine in the usual way [92JCS(P1)239]. 

The synthesized CPMV-alkyne 42 was subjected to the CuAAC reaction with 38. Due to the strong fluorescence of the cycloaddition product 43 as low as 0.5 nM, it could be detected without the interference of starting materials. TMV was initially subjected to an electrophilic substitution reaction at the ortho-position of the phenol ring of tyrosine-139 residues with diazonium salts to insert the alkyne functionality, giving derivative 44 [100]. The sequential CuAAC reaction was achieved with greatest efficiency yielding compound 45, and it was found that the TMV remained intact and stable throughout the reaction. 

The synthesis of pyrazolo[4,3-rf]-l,2,3-triazine starting from a pyrazolo-3-carbaldehyde derivative has been reported <00JIC168>. Azolo-l,2,4-triazine derivatives have been prepared via the reaction of functionalized thiazole derivatives with several heterocyclic diazonium salts <00JCR(S)206>. The reaction of 1,2,4-triazolium salt 67 with alkene 68 gives the pyrrolo[2,l-/][l,2,4]triazine 69 <00H(53)213>. 

Diazonium salts are another useful source of free radicals, and the formation of the reactive species can be achieved by reductive electrolysis or direct treatment with diazonium tetrafluoroborate salts [39]. By this route, several aryl derivatives could be introduced onto the nanotube sidewalls [40]. Aryl groups bearing halogen or alkyne functionalities are particularly interesting as they can be further reacted in Pd-catalyzed coupling reactions (Suzuki, Heck) or in click chemistry reactions to create products with great potential in materials science [41]. 

This preparative scheme leads to only 30% yield due to the side reactions between the meto-astatoaniline diazonium salt and astato-phenol, which cannot be eliminated even by continuous extraction of the product with n-heptane (167). All the astatophenols synthesized to date have been identified by either HPLC (99,104) or TLC (160,166,167). Their dissociation constants (KJ have been established from extraction experiments by measuring the relative distribution of compounds between aqueous borax buffer solutions and n-heptane as a function of acidity. On the basis of these derived values, the Hammett a-constants and hence the field (F) and resonance (R) effects have been estimated for these compounds (167) (see Table VI). The field effect for astatine was found to be considerably weaker than that for other halogens the resonance effect was similar to that for iodine (162). 

This type of titration is quite simple to carry out and is very useful for the analysis of sulphonamide antibiotics and aminobenzoic acid-derived local anaesthetics. Titration is carried out with acidified sodium nitrite causing the primary aromatic amine function to be converted to a diazonium salt shown in Figure 3.15 for sulphacetamide. 

There are a number of important reactions in this category and all of them involve at least one heteroatom functioning as a nucleophile and another as an electrophile. Diazo-tization of a variety of ortho-substituted anilines for instance, followed by intramolecular nucleophilic trapping of the corresponding diazonium salts by either nitrogen or carbon nucleophiles, is the basis of a series of very important syntheses of 1,2,3-benzotriazine and cinnoline derivatives, and this general approach has been widely exploited for the preparation of polycyclic systems. Representative examples are given in equations (51)—(54). 

Since A,A -disubstituted hydrazines are readily available from a variety of sources (see Volume I, Chapter 14), their dehydrogenation constitutes a widely applicable route to both aliphatic and aromatic azo compounds. Such oxidative procedures are of particular value in the aliphatic series because so many of the procedures applicable to aromatic compounds, such as the coupling with diazonium salts, have no counterpart. The oxidation reactions permit the formation not only of azoalkanes, but also of a host of azo compounds containing other functional groups, e.g., a-carbonyl azo compounds [83], a-nitrile azo compounds [84], azo derivatives of phosphoric acid [85], phenyl-phosphoric acid derivatives [86],... 

Mesoionic systems may be readily substituted by electrophiles. Thus the thiazolo mesoion (342) will couple with diazonium salts despite their relatively weak electrophilicity (80KGS621). Substitution in a fused heteroaromatic betaine azine ring, e.g. (343), also takes place with ease. The resonance form (344) of the mesoion (343) shows that the electrophile will attack at C-6. The substitution in this position is also predicted by MO calculations (73JHC487). Similarly the pyridine ring in pyridinium olates is active towards electrophiles and is substituted in the positions ortho and para to the olate function. Bromination of the 5-methyl derivative (321 R = Me) occurs exclusively in the 7-position which is rationalized via the intermediate (345). In the absence of a 5-substituent, attack in either the 5- or 7-position occurs the dibromide is readily formed. No bromination in the thiazole ring is observed. The 2-bromo derivative (346) has been made, however, by condensation between the appropriate mercaptopyridine and 1,1,2,2-tetrabromoethane. 

The nitrosamine (121) and especially diazonium salts (122) prepared from it, as well as their alkyl and aryl derivatives, are important synthetic intermediates (b-76MI4i200, p. 325). For conditions that decide between nitrosamine function or diazotization see (73jcS(P1)13S7). At room temperature or in concentrated hydrochloric acid nitrosamines derived from triazoles are unstable, and their decomposition products include chlorotriazoles (63LA(665)144) 5-nitrosamino-3-phenyl-l,2,4-triazole affords the 5-bromo compound with hydrobromic acid at 0 °C and reacts violently with hydroiodic acid (05lA(343)i). Thermal arylation with triazole nitrosamines is possible (73jcs(pi)i357). 

Now, let us take a simple functional group such as an OH and substitute it on our carbon atom. The carbinol we now have is capable of yielding only one C-C bond by way of substitution or one unsaturation on our carbon by means of elimination. Alcohols should then be classified under the FN = 1 group. Other oxygen based substituents such as ethers, carboxylic and sulfonic esters, and other heteroatom-containing derivatives such as amines and sulfides behave similarly, as long as we have only one of the heteroatoms substituted on our central carbon. By the same token, alkyl halides, diazonium salts, and even the carbenium ion itself are all capable of giving only one C-C bond with carbon... 

Introduction. The diazo group, N2X, is easily replaced by a number of other functional groups, such as OH, Cl, Br, I and CN. This affords a convenient method for the preparation of such derivatives as cannot be obtained by other methods except with great difficulty. The replacement of N2X by a halogen group is accomplished by heating the solution of diazonium salt with cuprous halide (Sandmeyer reaction) or with finely divided copper (Gatterman reaction). In the preparation of iodides the catalytic effect of copper is not required it is necessary only to pour the diazonium salt into a solution of potassium iodide and then to acidify the solution ... 

A variety of 2-pyrazolin-5-ones having carboxyl or carboxyl derivatives as substituents and a second functional group are known (Table XXXIII). Such compounds are usually prepared by methods already described, and only those compounds having an arylazo substituent as the second functional group will be discussed. These compounds have been extensively investigated because of their commercial importance as dyes. The important dye tartrazine is of this class. It is the trisodium salt of 4-(4-sulfophenylazo)-l-(4-sulfophenyl)-5-oxo-2-pyrazolin-3-carboxylic acid. These dyes exist largely as enol isomers. The principal means of preparation is coupling of a diazonium salt with a 5-oxo-2-pyrazolin-3-carboxylic acid or its derivatives. Another important preparation of these compounds (eq. 231) is by the reaction of... 

A surprising yield (60 %) of the more highly functionalized homoproaporphine derivative (112) has been obtained by the phenolic oxidative coupling reaction.128 On the other hand, application of the Pschorr sequence on (113) gave (114) as a mixture of diastereomers as well as anisaldehyde. Treatment of the diazonium salt corresponding to (113) with hypophosphorous acid also gave the diastereo-meric mixture (114) and, in addition, the deamination product and 4-methoxy-styrene.129... 

Besides the traditional coupling between alkenes and aryl (vinyl) halides, other functionalized aryl derivatives can also couple with alkenes in the Heck reaction, including aryl silanes,stannanes, bismuth, antimony,triflates, boric acid, phosphonic acid, carboxylic acid, and diazonium salt. ... 

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