Quaternary ammonium salts phase-transfer catalysts

On the other hand, A-tosylated aza-crowns were formed in good yields (50-94%) from the reaction of the bis-sulfonamides with dibromides or di-tosylates in aqueous alkali-toluene or benzene mixtures in the presence of quaternary ammonium salt phase-transfer catalysts. Some cyclizations did not depend on alkali concentration, but for the tri- or tetraaza-crowns, 50% alkali solutions were preferred. In the synthesis of A,jV -ditosyldiaza-18-crown-6 via the interaction of the bis-sulfonamide with a dibromide, dichloride, diiodide, or ditosylate using 50% aqueous sodium hydroxide-toluene or benzene solution in the phase-transfer reaction, the cyclization rate varied according to the leaving group, Br > OTs > I > Cl. In dilute alkaline solution (7.5%), the diiodide was more reactive than the ditosylate. This could be a result of the greater activity of water in the solution so that hydrolysis of the tosylate is more rapid and, therefore, there would be less tosylate to react with the amide (Bogatskii et al., 1984 Lukyanenko et al., 1987, 1988). 

Figure 12.3 Cinchonine- and cinchonidine-derived quaternary ammonium salt phase-transfer catalysts.

S)-40 Ar = 3,4,5-F3C0H2 Figure 12.9 Chiral binaphthyl- and biphenyl-modified quaternary ammonium salt phase-transfer catalysts... 

Phase transfer catalysis (PTC) refers to the transfer of ions or organic molecules between two liquid phases (usually water/organic) or a liquid and a solid phase using a catalyst as a transport shuttle. The most common system encountered is water/organic, hence the catalyst must have an appropriate hydrophilic/lipophilic balance to enable it to have compatibility with both phases. The most useful catalysts for these systems are quaternary ammonium salts. Commonly used catalysts for solid-liquid systems are crown ethers and poly glycol ethers. Starks (Figure 4.5) developed the mode of action of PTC in the 1970s. In its most simple... 

Rhodium(III) complexes [e.g. (i-Pr,P)2Rh(H)Cl2] in the presence of quaternary ammonium salts are excellent catalysts for the hydrogenolysis of chloroarenes under mild conditions [5] other labile substituents are unaffected. Hydrodehalogenation of haloaryl ketones over a palladium catalyst to give acylbenzenes is also aided by the addition of Aliquat [6]. In the absence of the phase-transfer catalyst, or when the hydrogenation is conducted in ethanol, the major product is the corresponding alkyl-benzene, which is also produced by hydrodehalogenation of the halobenzyl alcohols. 

Other methods are also available for the generation of dichlorocarbene which, in the presence of alkenes, forms 1,1-dichlorocyclopropanes, e.g. reaction of chloroform with oxirane, using a quaternary ammonium salt as the catalyst and an alkene (Houben-Weyl, Vol. 4/3, pp 374-381 and Vol. E19b, p 1530).The discovery of new, more convenient and equally efficient methods (especially phase-transfer catalysis) means that older approaches are unused at present. 

A new route to optically active trialkylphosphine oxides, and hence phosphines, has been reported. The key step, the conversion of the optically active phos-phinite (4) to phosphine oxide, is extremely sensitive to the solvent mixture used, and even under the most favourable conditions involves considerable racemization. Small levels of optical activity (0—8 % enantiomeric excess) have been induced in the phosphine oxide product by hydrolysis of the phosphonium salt (5) under phase-transfer conditions using optically active quaternary ammonium salts as chiral catalysts. ... 

A method has been described for the preparation of carbodiimides 1699 by dehydration of ureas 1696 with p-tosyl chloride under solid-liquid phase-transfer catalytic (PTC) conditions using solid potassium carbonate as a base and a lipophilic quaternary ammonium salt as a catalyst. The method is generally applicable for the synthesis of disubstituted carbodiimides, but is especially useful for un-symmetrically substituted carbodiimides. Yields of the resulting carbodiimides 1699 vary depending on the solvent (usually used at reflux temperature) in benzene or toluene yields of 66-98% are achieved, while in chloroform they are only 30-50% [1281]. 

Quaternary ammonium salts as we have seen are useful m synthetic organic chem istry as phase transfer catalysts In another more direct application quaternary ammo mum hydroxides are used as substrates m an elimination reaction to form alkenes... 

Halex rates can also be increased by phase-transfer catalysts (PTC) with widely varying stmctures quaternary ammonium salts (51—53) 18-crown-6-ether (54) pytidinium salts (55) quaternary phosphonium salts (56) and poly(ethylene glycol)s (57). Catalytic quantities of cesium duoride also enhance Halex reactions (58). 

Phase-tiansfei catalysis (PTC) is a technique by which leactions between substances located in diffeient phases aie biought about oi accelerated. Typically, one OI more of the reactants are organic Hquids or soHds dissolved in a nonpolar organic solvent and the coreactants are salts or alkah metal hydroxides in aqueous solution. Without a catalyst such reactions are often slow or do not occur at ah the phase-transfer catalyst, however, makes such conversions fast and efficient. Catalysts used most extensively are quaternary ammonium or phosphonium salts, and crown ethers and cryptates. Although isolated examples of PTC can be found in the early Hterature, it is only since the middle of the 1960s that the method has developed extensively. 

Reactions of the Side Chain. Benzyl chloride is hydrolyzed slowly by boiling water and more rapidly at elevated temperature and pressure in the presence of alkaHes (11). Reaction with aqueous sodium cyanide, preferably in the presence of a quaternary ammonium chloride, produces phenylacetonitrile [140-29-4] in high yield (12). The presence of a lower molecular-weight alcohol gives faster rates and higher yields. In the presence of suitable catalysts benzyl chloride reacts with carbon monoxide to produce phenylacetic acid [103-82-2] (13—15). With different catalyst systems in the presence of calcium hydroxide, double carbonylation to phenylpymvic acid [156-06-9] occurs (16). Benzyl esters are formed by heating benzyl chloride with the sodium salts of acids benzyl ethers by reaction with sodium alkoxides. The ease of ether formation is improved by the use of phase-transfer catalysts (17) (see Catalysis, phase-thansfer). 

It is important to make the distinction between the multiphasic catalysis concept and transfer-assisted organometallic reactions or phase-transfer catalysis (PTC). In this latter approach, a catalytic amount of quaternary ammonium salt [Q] [X] is present in an aqueous phase. The catalyst s lipophilic cation [Q] transports the reactant s anion [Y] to the organic phase, as an ion-pair, and the chemical reaction occurs in the organic phase of the two-phase organic/aqueous mixture [2]. 

Another catalytic system which has been successfully applied to the autoxidation of substituted toluenes involves the combination of Co/Br" with a quaternary ammonium salt as a phase transfer catalyst (ref. 20). For example, cobalt(II) chloride in combination with certain tetraalkylammonium bromides or tetraalkylphosphonium bromides afforded benzoic acid in 92 % yield from toluene at 135-160 °C and 15 bar (Fig. 19). It should be noted that this system does not require the use of acetic acid as solvent. The function of the phase transfer catalyst is presumably to solubilize the cobalt in the ArCH3 solvent via the formation of Q + [CoBr]. ... 

In this method, a catalyst is used to carry the nucleophile from the aqueous into the organic phase. As an example, simply heating and stirring a two-phase mixture of 1-chlorooctane for several days with aqueous NaCN gives essentially no yield of 1-cyanooctane. But if a small amount of an appropriate quaternary ammonium salt is added, the product is quantitatively formed in about 2 h." There are two principal types of phase-transfer catalyst. Though the action of the two types is somewhat different, the effects are the same. Both get the anion into the organic phase and allow it to be relatively free to react with the substrate. 

In liquid-solid processes reaction takes place between a liquid reactant and an insoluble or sparingly soluble solid which must be finely divided to speed up the process. Another measure to accelerate the process is to use an aqueous solution of a phase-transfer agent (typically a quaternary ammonium salt). The solid can also be a catalyst for reactions between liquid components, e.g. in acylations, carried out both conventionally in the presence of metal chlorides (mostly AICI3) or catalysed by zeolites and Grignard reactions. 

Benzylic quaternary phosphonium and ammonium salts are dealky-lated by mild heating and/or nucleophilic anions, particularly iodide (9) and thiolate (10), but also hydroxide (11). Most N-benzyl-pyridinium or quaternary aryl ammonium compounds are particularly susceptible (12). Decompositions of this sort have seriously limited the usefulness of solid phase-transfer catalysts derived from (chloromethyl)polystyrene (13, 14). 

Quaternary ammonium azides will displace halogens in a synthesis of alkyl azides. Dichloromethane has been used as a solvent, although this can slowly form diazido-methane which may be concentrated by distillation dining work-up, thereafter easily exploding [1]. An accident attributed to this cause is described, and acetonitrile recommended as a preferable solvent, supported polymeric azides, excess of which can be removed by filtration are also preferred in place of the tetrabutylam-monium salt [2]. A similar explosion was previously recorded when the quaternary azide was generated in situ from sodium azide and a phase transfer catalyst in a part aqueous system [3,4],... 

The 9,10-dihydrodiol of 3-MC (24a) was synthesized from 9-hy-droxy-3-MC by Method IV (86). Oxidation of this phenol with Fremy s salt in the presence of Adogen 464, a quaternary ammonium phase transfer catalyst, furnished 3-MC 9,10-dione. Reduction of the qui-none with NaBH -C gave pure 24a in good yield. Treatment of 24a with m-chloroperbenzoic acid was monitored by HPLC in order to optimize the yield of the anti diol epoxide (25 ) and minimize its decomposition. 

Arai et al.51 reported that by using a catalytic amount of chiral quaternary ammonium salt as a phase transfer catalyst, a catalytic cycle was established in asymmetric HWE reactions in the presence of an inorganic base. Although catalytic turnover and enantiomeric excess for this reaction are not high, this is one of the first cases of an asymmetric HWE reaction proceeding in a catalytic manner (Scheme 8-20). 

Cinchona alkaloids now occupy the central position in designing the chiral non-racemic phase transfer catalysts because they have various functional groups easily derivatized and are commercially available with cheap price. The quaternary ammonium salts derived from cinchona alkaloids as well as some other phase transfer catalysts are... 

The first practical and efficient asymmetric alkylation by use of chiral phase-transfer catalysts was the alkylation of the phenylindanone 15 (R1=Ph), reported by the Merck research group in 1984.114-161 By use of the quaternary ammonium salt 7 (R=4-CF3i X=Br) derived from cinchonine, the alkylated products 16 were obtained in excellent yield with high enantiomeric excess, as shown in... 

The catalytic asymmetric Horner-Wadsworth-Emmons reaction was realized by use of the quaternary ammonium salts 7 derived from cinchonine as a phase transfer catalyst.1631 Thus, tert-butylcyclo-hexanone 85 reacted with triethyl phosphonoacet-ate 86 together with RbOH-H20 in the presence of the ammonium salts 7, and then the product 87 was isolated after reesterification by treatment with acidic ethanol, as shown in Scheme 27 Among the... 

The following quaternary ammonium salts are used as phase transfer catalyst tetra-K-butylammonium chloride (TBAC), tetra-n-butylammonium bromide (TBAB), benzyltriethylammonium chloride (BTEAC), and benzyltriethylammo-nium bromide (BTEAB). Chlorinated hydrocarbons, such as dichloromethane (DCM), chloroform (CF), tetrachloromethane (TCM), 1,2-dichloromethane (DCE), and nitrobenzene (NB) are used as solvents. The effects of phase-transfer catalyst and solvent on the yield and reduced viscosity are summarized in Table 9.1. 

Onium salts, crown ethers, alkali metal salts or similar chelated salts, quaternary ammonium and phosphonium are some of the salts which have been widely used as phase transfer catalysts (PTC). The choice of phase transfer catalysts depends on a number of process factors, such as reaction system, solvent, temperature, removal and recovery of catalyst, base strength etc. 

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