Friedel-Crafts alkylation reaction polyalkylation

It should be noted that Scheme 5.1-44 shows idealized Friedel-Crafts allcylation reactions. In practice, there are a number of problems associated with the reaction. These include polyalkylation reactions, since the products of a Friedel-Crafts alkylation reaction are often more reactive than the starting material. Also, isomerization and rearrangement reactions can occur, and can result in a large number of products [74, 75]. The mechanism of Friedel-Crafts reactions is not straightforward, and it is possible to propose two or more different mechanisms for a given reaction. Examples of the typical processes occurring in a Friedel-Crafts alkylation reaction are given in Scheme 5.1-45 for the reaction between 1-chloropropane and benzene. 

The Friedel-Crafts alkylation reaction does not proceed successfully with aromatic reactants having EWG substituents. Another limitation is that each alkyl group that is introduced increases the reactivity of the ring toward further substitution, so polyalkylation can be a problem. Polyalkylation can be minimized by using the aromatic... 

Friedel-Crafts alkylation. Reaction of arenes with acid chlorides in CH2C12 with AICI3 (1 equiv.) and (C2H5)3SiH (2.5-3 equiv.) results in the alkylated arene by deoxygenation of the intermediate acylated arene. Yields of 95% are obtainable, and this procedure avoids the problem of polyalkylation observed in regular Friedel-Crafts reactions.3... 

Before explaining the previous data, it is important to understand why 54 is formed in the Friedel-Crafts alkylation reaction. This means that the reactivity of benzene derivatives must be addressed. If 54 is formed by a reaction of 53, then 53 must react with the intermediate carbocation more quickly than benzene. Why does 53 react more quickly than benzene In addition, this discussion must address the question of why polyalkylation is a problem but polyacylation is not. The answers to these questions will also explain the regioselectivity of the reaction. 

The reaction of benzene with a carbocation leads to an arene in what is known as Friedel-Crafts alkylation. The reaction of an alkyl halide with a strong Lewis acid gives a carbocation, which is subject to rearrangement. Friedel-Crafts alkylation reactions are subject to polyalkylation because the arene is more reactive than benzene 23, 24, 25, 26,82,86, 93, 94,102,113. 

Many variations of the reaction can be carried out, including halogenation, nitration, and sulfonation. Friedel-Crafts alkylation and acylation reactions, which involve reaction of an aromatic ling with carbocation electrophiles, are particularly useful. They are limited, however, by the fact that the aromatic ring must be at least as reactive as a halobenzene. In addition, polyalkylation and carbocation rearrangements often occur in Friedel-Crafts alkylation. 

Apart from the possibility of rearrangement, the main drawback in the preparative use of this Friedel-Crafts reaction is polyalkylation (cf. p. 153). The presence of an electron-withdrawing substituent is generally sufficient to inhibit Friedel-Crafts alkylation thus nitrobenzene is often used as a solvent for the reaction because A1C13 dissolves readily in it, thus avoiding a heterogeneous reaction. 

Ferrocene reacts with acetyl chloride and aluminum chloride to afford the acylated product (287) (Scheme 84). The Friedel-Crafts acylation of (284) is about 3.3 x 10 times faster than that of benzene. Use of these conditions it is difficult to avoid the formation of a disubstituted product unless only a stoichiometric amount of AlCft is used. Thus, while the acyl substituent present in (287) is somewhat deactivating, the relative rate of acylation of (287) is still rapid (1.9 x 10 faster than benzene). Formation of the diacylated product may be avoided by use of acetic anhydride and BF3-Et20. Electrophilic substitution of (284) under Vilsmeyer formylation, Maimich aminomethylation, or acetoxymercuration conditions gives (288), (289), and (290/291), respectively, in good yields. Racemic amine (289) (also available in two steps from (287)) is readily resolved, providing the classic entry to enantiomerically pure ferrocene derivatives that possess central chirality and/or planar chirality. Friedel Crafts alkylation of (284) proceeds with the formation of a mixture of mono- and polyalkyl-substituted ferrocenes. The reaction of (284) with other... 

A third limitation to the Friedel-Crafts alkylation is that it s often difficult to stop the reaction after a single substitution. Once the first alkyl group is on the ring, a second substitution reaction is facilitated for reasons we ll discuss in the nc.xt section. Thus, we often observe polyalkylation. Reaction of benzene with 1 mol equivalent of 2-chloro-2-inethylpropane, for example, yieldsp-di-A"t-butvlbenzene as the major product, along with small amounts of fc//-butyl-benzene and unreacted benzene. A high yield of monoalkylation product is obtained only when a large excess of benzene is used. 

Carbonium ions can be generated at a variety of oxidation levels. The alkyl carbocation can be generated from alkyl halides by reaction with a Lewis acid (RCl + AICI3) or by protonation of alcohols or alkenes. The reaction of an alkyl halide and aluminium trichloride with an aromatic ring is known as the Friedel-Crafts alkylation. The order of stability of a carbocation is tertiary > secondary > primary. Since many alkylation processes are slower than rearrangements, a secondary or tertiary carbocation may be formed before aromatic substitution occurs. Alkylation of benzene with 1-chloropropane in the presence of aluminium trichloride at 35 °C for 5 hours gave a 2 3 mixture of n- and isopropylbenzene (Scheme 4.5). Since the alkylbenzenes such as toluene and the xylenes (dimethylbenzenes) are more electron rich than benzene itself, it is difficult to prevent polysubsiitution and consequently mixtures of polyalkylated benzenes may be obtained. On the other hand, nitro compounds are sufficiently deactivated for the reaction to be unsuccessful. 

The carbonium ion may also be formed from an alkene or alcohol. The carbonium ion formed from any of these starting materials is particularly prone to rearrangement reactions. These are called Wagner-Meerwein rearrangements, and severely limit the synthetic utility of this reaction to form simple alkyl substituted aromatic compounds. The tendency to rearrange may be reduced if the acyl derivative is used instead. This modification is called the Friedel-Crafts acylation reaction, and it has the further advantage that normally only monoacylation occurs, instead of the polyalkylation that happens using the simple Friedel-Crafts reaction. 

It is not surprising that electrophilic aromatic substitutions were the first organic reactions investigated using acidic room-temperature chloro-almninate(III) ionic liquids. Indeed, chloroaluminate(ni) species combine their properties of good solvents for simple arenes to their role as Lewis acid catalysts. In Friedel-Craft alkylations, polyalkylation is common as well as the isomerisation of primary halides to secondary carbonium ions. 

Traditional Friedel-Crafts alkylation is not generally practicable in the fnran series, partly becanse of catalyst-indnced polymerisation and partly because of polyalkylation. Instances of preparatively nseful reactions inclnde prodnction of 2,5-di-i-bntylfuran from furan or fnroic acid and the isopropylation of methyl fnroate with donble snbstitntion, at the 3- and 4-positions. " ... 

Conventional Method of Producing Cumene (Fig. 75). In the past, the Friedel -Crafts alkylation of benzene was carried out together with the conversion of the polyalkylated isopropylbenzenes in a single reactor (a). The catalyst was produced directly in the reaction mixture from aluminum chippings and HCl. It formed a second separate organic phase in the reactor. The water present in the propene was simply removed mechanically, whereas the benzene used was dried over. sodium hydroxide. 

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