Phase catalytic conditions

In the following reaction under phase catalytic conditions... 

Disubstituted hydrazines and semicarbazones react with a-haloacyl halides under two-phase catalytic conditions to produce l,2-diazetidin-3-ones (20-85%) [35], whereas (3-haloacyl halides react with hydrazines to form pyrazolin-3-ones (ca. 30%). 

The reaction of dichloromethane with equimolar amounts of pyrazole and imidazole under liquid liquid two-phase catalytic conditions yields the three possible... 

The reactive anionic hydridometalcarbonyl complexes can be preformed from the neutral metal carbonyls using quaternary ammonium borohydrides either under homogeneous conditions or two-phase catalytic conditions [5] and are used in a range of reductive processes. The preparation of tetraethylammonium hydridotri-iron undecylcarbonyl is used as an illustrative example. 

The carbonylation of renewable 5(hydroxymethyl)-2-furfural (HMF) was reported to take place under aqueous-phase catalytic conditions with [Pd(tppts)3] as a catalyst [Eq. (8)] (83). 

Hydrogenation. Gas-phase catalytic hydrogenation of succinic anhydride yields y-butyrolactone [96-48-0] (GBL), tetrahydrofiiran [109-99-9] (THF), 1,4-butanediol (BDO), or a mixture of these products, depending on the experimental conditions. Catalysts mentioned in the Hterature include copper chromites with various additives (72), copper—zinc oxides with promoters (73—75), and mthenium (76). The same products are obtained by hquid-phase hydrogenation catalysts used include Pd with various modifiers on various carriers (77—80), Ru on C (81) or Ru complexes (82,83), Rh on C (79), Cu—Co—Mn oxides (84), Co—Ni—Re oxides (85), Cu—Ti oxides (86), Ca—Mo—Ni on diatomaceous earth (87), and Mo—Ba—Re oxides (88). Chemical reduction of succinic anhydride to GBL or THF can be performed with 2-propanol in the presence of Zr02 catalyst (89,90). 

Hydrochlorination of Ethylene. The exothermic vapor-phase reaction between ethylene [74-85-1] and hydrogen chloride [7647-01-0] can be carried out at 130—250°C under a variety of catalytic conditions. Yields are reported to be greater than 90% of theoretical (14). 

Direct halogenation of quinoxaline appears to be of limited value but pyrazine may be chlorinated in the vapor phase to give monochloropyrazine at 400 °C or at lower temperatures under catalytic conditions 72AHC(14)99, and at higher temperatures tetra-chloropyrazine formation occurs in high yields. Mention has already been made of direct chlorination (see Section 2.14.2.1) of phenazine. 

It is well known that aziridination with allylic ylides is difficult, due to the low reactivity of imines - relative to carbonyl compounds - towards ylide attack, although imines do react with highly reactive sulfur ylides such as Me2S+-CH2-. Dai and coworkers found aziridination with allylic ylides to be possible when the activated imines 22 were treated with allylic sulfonium salts 23 under phase-transfer conditions (Scheme 2.8) [15]. Although the stereoselectivities of the reaction were low, this was the first example of efficient preparation of vinylaziridines by an ylide route. Similar results were obtained with use of arsonium or telluronium salts [16]. The stereoselectivity of aziridination was improved by use of imines activated by a phosphinoyl group [17]. The same group also reported a catalytic sulfonium ylide-mediated aziridination to produce (2-phenylvinyl)aziridines, by treatment of arylsulfonylimines with cinnamyl bromide in the presence of solid K2C03 and catalytic dimethyl sulfide in MeCN [18]. Recently, the synthesis of 3-alkyl-2-vinyl-aziridines by extension of Dai s work was reported [19]. 

Amides are very weak nucleophiles, far too weak to attack alkyl halides, so they must first be converted to their conjugate bases. By this method, unsubstituted amides can be converted to N-substituted, or N-substituted to N,N-disubstituted, amides. Esters of sulfuric or sulfonic acids can also be substrates. Tertiary substrates give elimination. O-Alkylation is at times a side reaction. Both amides and sulfonamides have been alkylated under phase-transfer conditions. Lactams can be alkylated using similar procedures. Ethyl pyroglutamate (5-carboethoxy 2-pyrrolidinone) and related lactams were converted to N-alkyl derivatives via treatment with NaH (short contact time) followed by addition of the halide. 2-Pyrrolidinone derivatives can be alkylated using a similar procedure. Lactams can be reductively alkylated using aldehydes under catalytic hydrogenation... 

Empirical grey models based on non-isothermal experiments and tendency modelling will be discussed in more detail below. Identification of gross kinetics from non-isothermal data started in the 1940-ties and was mainly applied to fast gas-phase catalytic reactions with large heat effects. Reactor models for such reactions are mathematically isomorphical with those for batch reactors commonly used in fine chemicals manufacture. Hopefully, this technique can be successfully applied for fine chemistry processes. Tendency modelling is a modern technique developed at the end of 1980-ties. It has been designed for processing the data from (semi)batch reactors, also those run under non-isothermal conditions. 

More recently, Maruoka and co-workers have reported several new phase-transfer catalysts one of which incorporates a morpholine ring as part of an azoniaspirocyclic core 161 <2007TL4675>. These were employed in the catalytic enantioselective conjugate addition of a-benzylcyanoacetate to acetylenic methyl ketone under phase transfer conditions. 

Chiral thioureas have been synthesized and used as ligands for the asymmetric hydroformylation of styrene catalyzed by rhodium(I) complexes. The best results were obtained with /V-phenyl-TV -OS )-(l-phenylethyl)thiourea associated with a cationic rhodium(I) precursor, and asymmetric induction of 40% was then achieved.387,388 Chiral polyether-phosphite ligands derived from (5)-binaphthol were prepared and combined with [Rh(cod)2]BF4. These systems showed high activity, chemo- and regio-selectivity for the catalytic enantioselective hydroformylation of styrene in thermoregulated phase-transfer conditions. Ee values of up to 25% were obtained and recycling was possible without loss of enantioselectivity.389... 

Ironcarbonyl induces a similar reductive carbonylation of 150 with sodium methoxide [85], A catalytic cycle is formed by using CoCl2 and Ni(CN)2 as catalysts under phase-transfer conditions [86]. 

In addition to solvent-free processing, phase-transfer catalytic conditions (PTC) have also been widely employed as a processing technique in MAOS [15]. In phase-transfer catalysis, the reactants are situated in two separate phases, for example liquid-... 

Malonic acid allylic esters undergo intramolecular cyclization reaction under solid-liquid phase transfer catalytic conditions in the presence of Aliquat 336, potassium carbonate, and iodine (Eq. 60) [84]. Application of microwave irradiation to this procedure enabled 2-3-fold reduction in the reaction time compared with conventional conditions. It was found that use of microwaves affected the exo/endo diastereoi-somers ratio - a linear correlation between microwave power and exo isomer concentration was observed [85]. 

Reaction of organic halides with alkenes catalyzed by palladium compounds (Heck-type reaction) is known to be a useful method for carbon-carbon bond formation at unsubstituted vinyl positions. The first report on the application of microwave methodology to this type of reaction was published by Hallberg et al. in 1996 [86], Recently, the palladium catalyzed Heck coupling reaction induced by microwave irradiation was reported under solventless liquid-liquid phase-transfer catalytic conditions in the presence of potassium carbonate and a small amount of [Pd(PPh3)2Cl2]-TBAB as a catalyst [87]. The arylation of alkenes with aryl iodides proceeded smoothly to afford exclusively trans product in high yields (86-93%) (Eq. 61). 

E. J. Corey, F. Xu, M. C. Noe, A Rational Approach to Catalytic Enantioselective Enolate Alkylation Using a Structurally Rigidified and Defined Chiral Quaternary Ammonium Salt under Phase Transfer Conditions , J. Am. Chem. Soc, 1997,119,12414-12415. 

Ohtomi et al. (1976) have studied the catalytic effect of polypode ligands, such as [ 116] on the reactions of alkyl halides under liquid-liquid phase-transfer conditions (Table 34). Primary alkyl iodides are seen to be more reactive than the corresponding bromides. In contrast, the reactivity towards CN- declines in the order RBr > RI > RC1. It is interesting to note that this order differs from that observed in solid-liquid two-phase systems catalysed by crown ethers (Cook et al., 1974). 

The yields of arenesulphonic acids (-80%) via the reaction of activated haloarenes with potassium sulphite under phase-transfer catalytic conditions [62, 63] are no better than conventional non-catalytic methods, although reaction conditions are less severe. There is evidence that indicates the initial attack by the sulphite anion is at C-5. Surprisingly, tri-n-butylamine is a better catalyst, producing higher yields (>90%). 

The nucleophilic displacement of the halogen from 2,4-dinitrohalobenzenes by azide ion is catalysed by macrotricyclic ammonium salts [69], Kinetic studies indicate that the azide ion is entrapped and transported within the macrocyclic cage. The highly explosive tetra-azido-p-benzoquinone is obtained when the tetrachloro-quinone is reacted with an excess of sodium azide under phase-transfer catalytic conditions [70]. When only a twofold excess of the azide is used, the 2,5-diazido-3,6-dichloro compound is obtained. 

Terminal alkynes are converted in high yield (70-80%) into 1-iodoalkynes by their copper-catalysed reaction with iodine under phase-transfer catalytic conditions... 

The application of phase-transfer catalysis to the Williamson synthesis of ethers has been exploited widely and is far superior to any classical method for the synthesis of aliphatic ethers. Probably the first example of the use of a quaternary ammonium salt to promote a nucleophilic substitution reaction is the formation of a benzyl ether using a stoichiometric amount of tetraethylammonium hydroxide [1]. Starks mentions the potential value of the quaternary ammonium catalyst for Williamson synthesis of ethers [2] and its versatility in the synthesis of methyl ethers and other alkyl ethers was soon established [3-5]. The procedure has considerable advantages over the classical Williamson synthesis both in reaction time and yields and is certainly more convenient than the use of diazomethane for the preparation of methyl ethers. Under liquidrliquid two-phase conditions, tertiary and secondary alcohols react less readily than do primary alcohols, and secondary alkyl halides tend to be ineffective. However, reactions which one might expect to be sterically inhibited are successful under phase-transfer catalytic conditions [e.g. 6]. Microwave irradiation and solidrliquid phase-transfer catalytic conditions reduce reaction times considerably [7]. 

The highly hydrophilic alcohols, pentaerythritol and 2-ethyl-2-hydroxymethyl-propan-l,3-diol, can be converted into their corresponding ethers in good yields under phase-transfer catalytic conditions [12]. Etherification of pentaerythritol tends to yield the trialkoxy derivative and kinetics of the reaction have been shown to be controlled by the solubility of the ammonium salt of the tris-ether in the organic phase and the equilibrium between the tris-ether and its sodium salt [13]. Total etherification of the tetra-ol is attained in good yield when reactive haloalkanes are used, and tetra-rt-octylammonium, in preference to tetra-n-butylammonium, bromide [12, 13]. 

A./V-Dialkylhydroxylamines and oximes are readily alkylated to produce O-alkyl ethers [34-36] and oximes also react rapidly with dichloromethane to form the methylene dioximes [36-38]. O-Benzylhydroxylamine can be prepared on a large scale by alkylation of A-hydroxyphthalimidc under phase-transfer catalytic conditions and subsequent solvolysis of the imide system [39]. 

A convenient catalysed two-phase methoxymethylation of phenols (>80%) has been described [18], This is an improvement on the standard reaction, which normally requires anhydrous conditions. 1-Naphthol is reported to be 0-mcthylatcd under catalytic conditions with only a minor amount (ca. 3%) of C-methylation at the 2-position [19]. 

Hydroxycoumarins are alkylated under extremely mild basic liquiddiquid phase-transfer catalytic conditions to produce the ethers and 4-alkylated derivatives 141 ]. The major product tends to be the ether (50-60%) but the yield of the C-alkyl-ated product is significant with allyl bromide and with propargyl bromide, where rearrangement of the allenic derivative occurs. 

Methyl esters undergo trans-esterification with the quaternary ammonium salts at high temperature and the reaction has been used with some effect for the preparation of, for example, n-butyl esters by heating the methyl ester with tetra-n-butylammo-nium chloride at 140°C [31]. Optimum yields (>75%) are obtained in HMPA or in the absence of a solvent. A two-step (one-pot) trans-esterification under phase-transfer catalysed conditions in which the carboxylate anion generated by initially hydrolysis of the ester is alkylated has been reported for Schiff s bases of a-amino acids [32] and for A-alkoxycarbonylmethyl [1-lactams [33]. Direct trans-esterification of methyl and ethyl esters with alcohols under basic catalytic conditions occurs in good yield in the presence of Aliquat [34, 35]. 

Acyloxy-l-cyanoalkanes [45, 46], which can be used as precursors for ketones [47], a-hydroxy ketones [48] and 1,4-dicarbonyl compounds [47], are prepared in one pot from the appropriate aldehyde, sodium or potassium cyanide, and the acylating agent under phase-transfer catalytic conditions [47-49]. Attempts to synthesize chiral cyanhydrins using chiral phase-transfer catalysts have been unsuccessful (see Section 12.3). 

An interesting preparation of alkyl carboxylates in high yield (Table 3.14) from the sodium salt of the carboxylic acids under mild phase-transfer catalytic conditions involves their reaction with alkyl chlorosulphate [50] and has been used with success in the preparation of alkyl esters derived from p-lactam antibiotics. The procedure is also excellent for the production of chloromethyl esters, particularly where the carboxylic acids will not withstand the classical Lewis acid-catalysed procedure using an acid chloride and formaldehyde, or where the use of iodochloromethane [51] results in the formation of the bis(acyloxy)methane. The procedure has been applied with some success to the synthesis of chloromethyl A-protected a-amino carboxylates [52],... 

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