Substitution reactions substrate

The attack by a reagent of a molecule might be hampered by the presence of other atoms near the reaction site. The larger these atoms and the more are there, the higher is the geometric restriction, the steric hindrance, on reactivity. Figure 3-6e illustrates this for the attack of a nucleophile on the substrate in a nucleophilic aliphatic substitution reaction. 

The most widely studied electrophilic substitution reactions are haloge-nation and nitration. Two main types of substrates are possible alkyl-thiazoles and arylthiazoles. 

In view of the overall increased reactivity of furan compared with thiophene it would be anticipated that furan would be less regioselective in its reactions with electrophiles than thiophene. Possible reasons for the high regioselectivity of furan in electrophilic substitution reactions include complex formation between substrates and reagents and the ability of heteroatoms to assist in the stabilization of cationic intermediates (80CHE1195). 

The range of preparatively useful electrophilic substitution reactions is often limited by the acid sensitivity of the substrates. Whereas thiophene can be successfully sulfonated in 95% sulfuric acid at room temperature, such strongly acidic conditions cannot be used for the sulfonation of furan or pyrrole. Attempts to nitrate thiophene, furan or pyrrole under conditions used to nitrate benzene and its derivatives invariably result in failure. In the... 

Sulfonate esters are especially useful substrates in nucleophilic substitution reactions used in synthesis. They have a high level of reactivity, and, unlike alkyl halides, they can be prepared from alcohols by reactions that do not directly involve bonds to the carbon atom imdeigoing substitution. The latter aspect is particularly important in cases in which the stereochemical and structural integrity of the reactant must be maintained. Sulfonate esters are usually prepared by reaction of an alcohol with a sulfonyl halide in the presence of pyridine ... 

Trifluoromethanesulfonate (triflate) ion is an exceptionally good leaving grov. It can be used for nucleophilic substitution reactions on unreactive substrates. Acetolysis of cyclopropyl triflate, for example, occurs 10 times faster than acetolysis of cyclopropyl tosylate. Table 5.11 gives a conqiarison of the triftate group with some other common leaving groups. 

Chlorobutyl rubber is prepared by chlorination of butyl rubber (chlorine content is about 1 wt%). This is a substitution reaction produced at the allylic position, so little carbon-carbon double unsaturation is lost. Therefore, chlorobutyl rubber has enhanced reactivity of the carbon-carbon double bonds and supplies additional reactive sites for cross-linking. Furthermore, enhanced adhesion is obtained to polar substrates and it can be blended with other, more unsaturated elastomers. 

This reaction is of synthetic value in that a-halo acids are reactive substrates in nucleophilic substitution reactions. 

Strong acids promote SnI substitution reactions by converting an electron-rich ( basic ) atom on the substrate into a good leaving group, e.g., for substitution reactions of tert-butyl derivatives. 

A more practical solution to this problem was reported by Larson, in which the amide substrate 20 was treated with oxalyl chloride to afford a 2-chlorooxazolidine-4,5-dione 23. Reaction of this substrate with FeCL affords a reactive A-acyl iminium ion intermediate 24, which undergoes an intramolecular electrophilic aromatic substitution reaction to provide 25. Deprotection of 25 with acidic methanol affords the desired dihydroisoquinoline products 22. This strategy avoids the problematic nitrilium ion intermediate, and provides generally good yields of 3-aryl dihydroisoquinolines. 

Oxidative addition of XY substrates to [IrL2(/x-pz)]2 [La = (CO)2, cod] and [Ir(CD)(PPh3)(/i,-pz)]2 occurs via a two-center, two-electron route toward the iridium-iridium bond-containing species 131 (960M3785 980M2743). Complex 132, which is prepared by the ligand-substitution reaction from [Ir(CO)2 (/x-pz)]2, adds methyl iodide to give 133. 

The effect of a nitro group at the 6 position on the nucleophilic substitution reaction has been examined using l-methoxy-6-nitroindole (82) as a substrate (2001H1151). The reaction with NaOMe in refluxing DMF generates 6-nitroin-dole (83, 57%), 2-methoxy- (199, 22%), and 3-methoxy-6-nitroindoles (84, 6%) (Scheme 29). The formation of 199 and 84 can be explained by the SN2 -type nucleophilic substitution reaction at the 2 and 3 positions, respectively, with the... 

Copper-mediated Substitution Reactions of Extended Substrates... 

Hie use of chiral catalysts as an approach to enantiomer icaliy enriched products by means of coppet-mediated substitution reactions is covered in this chapter. Reactions in which a chiral auxiliary resides in the leaving group of the substrate w ill also he dealt with, since these reactions provide direct and efBcient routes to single enantiomers of the desired products. Most studies so far have been concerned with allylic substrates, with a new chiral center being produced in the course of a selec-... 

Depending on the substrate and the other reaction parameters, very higli re-gioselectivilies towards either a or y suhstilution can he obtained. In cetLain cases, the regioselectivity can easily he switclied between the two modes by changing the reaction conditions [11]. Compared to, for example, palladiumiO)-catalyzed allylic substitution reactions, the possibility of switching between S j2 and S j2 selectivity... 

S ]2 -selective reactions between primary allylic substrates and otganocoppet reagents testiU in the creation of new Chirality in previously aChital molecules, and it is tempting to try to take advantage of this for the development of enantioselective allylic substitution reactions. 

Denniatk and co-wotkets teporied tlie brst example in 1990 [16], using substrates 1, s7ntliesized Grom adiital allylic alcohols and tead dy ava dable optically active amine auxdiaries. Substrates 1 were tlien employed in coppet-niediaied allylic substitution reactions, as shown in Sdienie 8.4. 

It may be concluded from die different examples sliown here tiiat die enantio-selective copper-catalyzed allylic substitution reaction needs ftirdier improvemetiL High enantioselectivities can be obtained if diirality is present in tiie leaving group of die substrate, but widi external diiral ligands, enantioselectivities in excess of 9096 ee have only been obtained in one system, limited to die introduction of die sterically hindered neopeatyl group. 

The synthesis of an alkylated aromatic compound 3 by reaction of an aromatic substrate 1 with an alkyl halide 2, catalyzed by a Lewis acid, is called the Friedel-Crafts alkylation This method is closely related to the Friedel-Crafts acylation. Instead of the alkyl halide, an alcohol or alkene can be used as reactant for the aromatic substrate under Friedel-Crafts conditions. The general principle is the intermediate formation of a carbenium ion species, which is capable of reacting as the electrophile in an electrophilic aromatic substitution reaction. 

Another formylation reaction, which is named after Gattermann, is the Gatter-mann-Koch reaction. This is the reaction of an aromatic substrate with carbon monoxide and hydrogen chloride (gas) in the presence of a Lewis acid catalyst. Similar to the Gattermann reaction, the electrophilic agent 9 is generated, which then reacts with the aromatic substrate in an electrophilic aromatic substitution reaction to yield the formylated aromatic compound 10 ... 

In an initial step the reactive formylating agent is formed from N,N-dimethylformamide (DMF) 2 and phosphorus oxychloride. Other N,N-disubstituted formamides have also found application for example A -methyl-A -phenylformamide is often used. The formylating agent is likely to be a chloromethyl iminium salt 4—also called the Vilsmeier complex (however its actual structure is not rigorously known)—that acts as the electrophile in an electrophilic substitution reaction with the aromatic substrate 1 (see also Friedel-Crafts acylation reaction) ... 

The initial product 5 of the electrophilic aromatic substitution step is unstable and easily hydrolyzes to yield the aromatic aldehyde 3 as the final reaction product. With mo o-substituted aromatic substrates the para-substituted aldehyde is formed preferentially. 

The chain propagation step consists of a reaction of allylic radical 3 with a bromine molecule to give the allylic bromide 2 and a bromine radical. The intermediate allylic radical 3 is stabilized by delocalization of the unpaired electron due to resonance (see below). A similar stabilizing effect due to resonance is also possible for benzylic radicals a benzylic bromination of appropriately substituted aromatic substrates is therefore possible, and proceeds in good yields. 

---