Halogenation heteroaromatic rings

Haloarenes routinely form XB. The same holds for haloheteroarenes and when the heteroaromatic ring is positively charged, the halogen becomes a particularly good XB donor [89-94]. This strategy has been applied with particular success in order to control the packing of bromo- and iodo-... 

Substitution of halogens on heteroaromatic rings is a common way to introduce new functionalities. The product from reaction 6 (Scheme 6) was required on a 100-g scale as an intermediate. In the literature, this exchange was done on a 5-g scale using ammonia in ethanol in a sealed tube under pressure for 6 h at 125-130°C with a yield of 76% (Bendich et al. 1954). Because of the lack of a suitable autoclave for high-pressure reactions, we choose the microwave reactor for scale-up trials. Using our Synthos 3000 equipment, we found suitable conditions with only minimal optimization at 170°C for 180 min and obtained the desired product on a 60-g scale in 83% yield. 

Halogen substituents are of course easy to introduce to heteroaromatic rings, and they also enhance the acidity of the ring protons. n-BuLi will, for example, lithiate the tetrafluoropyridine 179 at —60°C in ether ° but with pyridine itself it leads to addition/reoxidation products . Addition to the ring is the major product with 2-fluoropyridine 180, though some metaUation can be detected selectivity in favour of metaUation is complete with LDA in THF at —75 °C or with phenyUithium and catalytic -Pr2NH at —50°C (Scheme 90) . Similar results are obtained with quinolines . 

The a-, f3- and y-halogeno substituents in pyridines and their benzo analogues are each more susceptible to nucleophilic substitution than is the case for halobenzenes because of the overall electron deficiency of the heteroaromatic ring. Furthermore, halogen substituents a and y to nitrogen are usually more reactive than /3-halogens and this is particularly so in pyridinium type systems. 

To eliminate arylating activity, displace halogens at the ortho position to the meta or para positions in pyridine-type heteroaromatic rings. 

Grimmett, M. R., Advances in Imidazole Chemistry, 12, 103 27, 241 Electrophilic Substitution in the Azines, 47, 325 Halogenation of Heterocycles I. Five-member ed Rings, 57, 291 II. Six and Seven-numbered Rings, 58, 271 III. Heterocycles Fused to Other Aromatic and Heteroaromatic Rings, 59, 245. 

Halogenation of heterocycles five-membered rings, 57, 291 fused to other aromatic and heteroaromatic rings, 59, 245 six- and seven-membered rings, 58, 271 of heterocyclic compounds, 7, 1 Hammett equation, applications to... 

Halogenation of heterocycles fused with other aromatic or heteroaromatic rings 93AHC(59)245. 

The reducibility of a halogenated heteroaromatic system depends on the heteroaromatic ring, the kind of halogen, and the position of the substituent. Iodides are more easily reducible than bromides which, in turn, are easier than chlorides. Halogen substituents in positions activated toward nucleophilic attack are preferentially reduced. 

The Pd-catalyzed oxidation of unfunctionalized C-H bonds has recently been described by Sanford. These reactions lead to the direct, regioselective installation of hydroxyl groups or halogen atoms onto aromatic and heteroaromatic ring systems. For example, benzo[//]quinoline is selectively converted to 10-chlorobenzo[A]quinoline upon treatment with catalytic Pd(OAc)2 and NCS [103]. As shown below, these transformations are also effective for the installation of oxygenated functional groups including acetates and alkyl ethers. The oxidative functionalization of. sy/ C-H bonds has also been achieved [104]. 

In many cases, substituents linked to a pyrrole, furan or thiophene ring show similar reactivity to those linked to a benzenoid nucleus. This generalization is not true for amino or hydroxyl groups. Hydroxy compounds exist largely, or entirely, in an alternative nonaromatic tautomeric form. Derivatives of this type show little resemblance in their reactions to anilines or phenols. Thienyl- and especially pyrryl- and furyl-methyl halides show enhanced reactivity compared with benzyl halides because the halogen is made more labile by electron release of the type shown below. Hydroxymethyl and aminomethyl groups on heteroaromatic nuclei are activated to nucleophilic attack by a similar effect. 

Nucleophilic substitution of halogen atom in aromatic and heteroaromatic halides with a hydroxyamino group proceeds only in substrates that are activated by a strong electron-withdrawing substituent in the benzene ring (e.g. 27, equation 17). Despite this limitation this reaction is useful for synthesis of arylhydroxylamines and usually provides good yields of products. Along with activated aryl halides and sulfonates, activated methyl aryl ethers such as 28 can be used (equation 18). 

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