Carboxylic acid derived catalyst

When a Br nsted base functions catalytically by sharing an electron pair with a proton, it is acting as a general base catalyst, but when it shares the electron with an atom other than the proton it is (by definition) acting as a nucleophile. This other atom (electrophilic site) is usually carbon, but in organic chemistry it might also be, for example, phosphorus or silicon, whereas in inorganic chemistry it could be the central metal ion in a coordination complex. Here we consider nucleophilic reactions at unsaturated carbon, primarily at carbonyl carbon. Nucleophilic reactions of carboxylic acid derivatives have been well studied. These acyl transfer reactions can be represented by... 

The formulated mechanism is supported by the finding that no halogen from the phosphorus trihalide is transferred to the a-carbon of the carboxylic acid. For instance, the reaction of a carboxylic acid with phosphorus tribromide and chlorine yields exclusively an a-chlorinated carboxylic acid. In addition, carboxylic acid derivatives that enolize easily—e.g. acyl halides and anhydrides—do react without a catalyst present. 

Although the aminolysis of esters to amides is auseful synthetic operation, usually it presents some disadvantages in terms of drastic reaction conditions, long reaction times or strong alkali metal as catalyst, which are usually not compatible with other functional groups in the molecule [6]. For this reason, enzymatic aminolysis of carboxylic acid derivatives offers a clean and ecological way for the preparation of different kind of amines and amides in a regio-, chemo-, and enantioselective manner. 

Diels-AIder reactions were utilized to prepare isoquinoline derivatives. Various tetrahydroisoquinoline-3-carboxylic acid derivatives were prepared by an enyne metathesis followed by a Diels-AIder reaction. For example the enyne 71 was treated with Grubb s catalyst to afford diene 72 in 65% yield. Subsequent Diels-AIder reaction and oxidation gave tetrahydroisoquinoline 73 in 93% yield <0OCC5O3>. Dihydrosoquinoline 75 was prepared... 

The cyclocondensation of l,3-amino alcohols with carboxylic acid derivatives is a method often applied for the synthesis of 5,6-dihydro-4/7-l,3-oxazines <1996CHEC-II(6)301 >. Ebsorb-4, a weakly acidic zeolite-type adsorbent with 4 A pore size, proved an efficient catalyst of the cyclization of benzoic acid and 3-aminopropanol <2002TL3985>. In the presence of zinc chloride as a catalyst, the expulsion of ammonia drove the reactions of 3-aminopropanol with nitriles to completion, affording 2-substituted 5,6-dihydro-47f-l,3-oxazines in good yields... 

Carboxylic acid derivatives are compounds that possess an acyl group (R—C=0) linked to an electronegative atom, e.g. —Cl, —CO2 R, —OR or —NH2. They can be converted to carboxylic acids via simple acidic or basic hydrolysis. The important acid derivatives are acid chlorides, acid anhydrides, esters and amides. Usually nitriles are also considered as carboxylic acid derivatives. Although nitriles are not directly carboxylic acid derivatives, they are conveniently hydrolysed to carboxylic acids by acid or base catalysts. Moreover, nitriles can be easily prepared through dehydration of amides, which are carboxylic acid derivatives. 

The fate of the acyl palladium complex depends on the circumstances. In the presence of a suitable nucleophile (alcohol, amine) it is converted into the corresponding carboxylic acid derivative. The side product, a palladium hydride is converted to the active form of the catalyst in a reductive elimination step, resulting in the formation of an equimolar amount of acid, which is quenched by an added base (in most cases the excess of the nucleophile). 

Unsaturated hydrocarbons (alkenes, dienes) react with carbon monoxide and a proton source (H20, alcohols, amines, acids) under strong acidic conditions to form carboxylic acids or carboxylic acid derivatives. Since a carbocationic mechanism is operative, not only alkenes but also other compounds that can serve as the carbocation source (alcohols, saturated hydrocarbons) can be carboxylated. Metal catalysts can also effect the carboxylation of alkenes, dienes, alkynes, and alcohols. 

The transformation of alkenes in the presence of Group VUI metal catalysts affords carboxylic acids or carboxylic acid derivatives depending on the protic reagent used 10 14-16 23 "7-123... 

The hydrocarboxylation reaction of alkenes and alkynes is one which utilizes carbon monoxide to produce carboxylic acid derivatives. The source of hydrogen is a protic solvent (equation 35) dihydrogen is not usually added to the reaction. There are a number of variations to this reaction, since the solvent can be water, alcohols, amines, acids, etc. The catalysts can be Group VIII-X transition metals, but cobalt, rhodium, nickel, palladium and platinum have found the most use. 

Deng and co-workers have also applied the cinchona derivatives to the kinetic resolution of protected a-amino acid N-carboxyanhydrides 51 [48]. A variety of alkyl and aryl-substituted amino acids may be prepared with high se-lectivities (krei=23-170, see Scheme 10). Hydrolysis of the starting material, in the presence of the product and catalyst, followed by extractive workup allows for recovery of ester, carboxylic acid, and catalyst. The catalyst may be recycled with little effect on selectivity (run 1, krei=114 run 2, krei=104). The reaction exhibits first-order dependence on methanol and catalyst and a kinetic isotope effect (A MeOH/ MeOD=l-3). The authors postulate that this is most consistent with a mechanism wherein rate-determining attack of alcohol is facilitated by (DHQD)2AQN acting as a general base. 5-Alkyl 1,3-dioxolanes 52 may also... 

Aldol condensationsPhase-transfer condensation of aldehydes with ,/ -unsaturated carboxylic acid derivatives is possible with anhydrous K2COj as base and Aliquat 336 as catalyst. 

Aluminum chloride is used in the petroleum industries and various aspects of organic chemistry technology. For example, aluminum chloride is a catalyst in the alkylation of paraffins and aromatic hydrocarbons by olefins and also in the formation of complex ketones, aldehydes, and carboxylic acid derivatives. 

A microwave-assisted one-pot approach towards 2,4,5-trisubstituted oxazoles employed a hypervalent iodine (III) catalyst to bring about the reaction of ketones, 1,3-diketones and /3-keto-carboxylic acid derivatives with amides [75]. Microwave dielectric heating was also successfully utilized in a solid-supported, solvent-free synthesis of 2-phenyl-oxazol-5-ones (azlac-tones) [76] as well as in a solution phase synthesis of isomeric 2-phenyl-oxazol-4-ones (oxalactims) [77]. 

---