Ethyl acetate synthesis

In our structural formulas, zinc with its three ligands could, without any fundamental difficulty, take the place of the aluminum with four ligands. In this connection, attention may be drawn to the technical ethyl acetate synthesis according to Tishchenko, in which the catalytically active aluminum may be replaced in part, or even wholly, by zinc. 

C. Reaction with Ethyl Acetate Synthesis of Fused Carbocyclcs... 

Hydrogenation of 1,3,5-trimethylbenzene Methanol synthesis Ethyl acetate synthesis Methyl acetate synthesis Propene metathesis. 

In this section, four examples illustrating the application of the rate-based approach discussed above to the RD modeling are presented. The systems selected are methyl acetate synthesis, MTBE synthesis, ethyl acetate synthesis and transesterification of dimethyl carbonate. In the first example, dynamic process modeling is highlighted, whereas in three other examples, different aspects of steady-state modeling are discussed. 

Figure 10.14 Sketch of the basic column configuration for ethyl acetate synthesis.

A homogeneously catalyzed RD for the ethyl acetate synthesis was investigated by Kenig et al. [105], whereas a successful model validation was performed using the experimental data obtained in a glass bubble cup tray column. 

In recently developed processes for the ethyl acetate synthesis, heterogeneously catalyzed RD has also been applied. Kolena et aL [107] and Wu and lin [108] suggested the combination of a pre-reactor and a RD column to carry out the reaction. The only difference between these processes is the location of the feed to the RD column. The process of Kolena et al. [107] is nowadays commercialized by Sulzer Chemtech Ltd. [109]. 

Here we give another example of heterogeneously catalyzed ethyl acetate synthesis via RD, with two different column scales studied, namely a 50-mm and a 162-mm diameter columns (see [52]). The principal column setup is shown in Fig. 10.14. The columns consist of three packed sections, whereas the middle part is equipped with structured catalytic internals. The reactants are fed above and below the reactive section. 

Table 10.4 Pilot-plant characteristics for the ethyl acetate synthesis.

Figure 10.17 represents a comparison of the concentration profiles in two different ethyl acetate synthesis modes, with and without a decanter. The investigation is performed for the pilot-scale column, with a molar feed ratio acetic acid/ethanol equal to 1.2, reflux ratio equal to 3, and a total feed rate equal to 30kg/h. The distillate-to-feed ratio is set to 0.9. The simulations reveal that the conversion with the liquid-liquid separator is about 5% higher that without a decanter, since there is less water and more acetic acid in the catalytic section. Improved conversion and product enrichment due to liquid-liquid separation result in a significant (29%) improvement of the product purity. Finally, because there is less condensed water in the reflux to be evaporated, the heat duty is reduced by up to 26%. 

M. Kleker, E. Y. Kenig, A. Gorak, A. P. Markusse, G. Kwant, P. Moritz, Investigation of Different Column Configurations for the Ethyl Acetate Synthesis via Reactive Distillation, Chem. Eng. Process., 2004, 43, 791-801. 

Heteropolyacid CSxH3 xPW 12O40 W-OH-W Ethyl acetate synthesis Gas/sohd 140-250... 

Carbon nano-tube basicity influence in R-l-phenyl ethyl acetate synthesis... 

A Methylamino)phenol. This derivative (15) is easily soluble ia ethyl acetate, ethanol, diethyl ether, and benzene. It is also soluble ia hot water, but only spatingly soluble ia cold water. Industrial synthesis is by heating 3-(A/-methylamino)benzenesulfonic acid with sodium hydroxide at 200—220°C (179) or by the reaction of resorciaol with methylamiae ia the presence of aqueous phosphoric acid at 200°C (180). 

Pyrrohdinone (2-pyrrohdone, butyrolactam or 2-Pyrol) (27) was first reported in 1889 as a product of the dehydration of 4-aminobutanoic acid (49). The synthesis used for commercial manufacture, ie, condensation of butyrolactone with ammonia at high temperatures, was first described in 1936 (50). Other synthetic routes include carbon monoxide insertion into allylamine (51,52), hydrolytic hydrogenation of succinonitnle (53,54), and hydrogenation of ammoniacal solutions of maleic or succinic acids (55—57). Properties of 2-pyrrohdinone are Hsted in Table 2. 2-Pyrrohdinone is completely miscible with water, lower alcohols, lower ketones, ether, ethyl acetate, chloroform, and benzene. It is soluble to ca 1 wt % in aUphatic hydrocarbons. 

Alcohols. The direct synthesis of esters by dehydrogenation or oxidative hydrogenation of alcohols offers a simple method for the preparation of certain types of esters, such as ethyl acetate (96—98) ... 

The photolytic and thermolytic decomposition of azides in the presence of olefins has been applied to aziridine synthesis. However, only a limited number of steroid aziridines have been prepared in this manner. The patent literature reports the use of cyanogen azide at ca. 50° for 24 hours in ethyl acetate for the preparation of an A-nor- and a B-norsteroidal aziridine. The addition is believed to proceed via a triazoline. The reaction of cholest-2-ene with ethyl azidoformate takes place in a nonselective manner to produce a mixture of substances, including C—H insertion products. 

It was reported that the Niemeiitowski synthesis of 4-hydroxy-3-iiitro-7-pheiiyl-l,8-iiaphthyridiii-2(lH)-oiie (25) from ethyl 2-amiiio-6-pheiiyhii-cotiiiate (23) and ethyl nitroacetate (24) in the presence of sodium was unsuccessful, producing only traces of (25), while condensation of ethyl 2-amino-6-phenylnicotinate (23) with the less reactive ethyl acetate resulted in the formation of 4-hydroxy-7-phenyl-l,8-naphthyridin-2(lH)-one in good yield [66JCS(C)315]. It seems that the more reactive nitroacetate tends to precipitate rapidly from the reaction mixture as its sodio derivative, which explains the low yield of (25). 

A similar synthesis starting with l-(2-nitrobenzyl)pyrrol-2-aldehyde used ethanol-ethyl acetate as solvent (62). Indoles are prepared in excellent yield by hydrogenation of o-nitrobenzyl ketones over Pd-on-C (i). Azaindoles are correspondingly prepared from nitropyridines (97). 

Synthesis of 9-oxo-11 CH,1 Sol-bis-(2-tetrahydropyranytoxy)-16,16-dimethyl-prosta-trans-2, trans-13-dienoicacid 4gof ethyl 9a-hydroxy-1 la,1 5a-bis-(2-tetrahydropyranyloxy )-16,16-dimethyl-prosta-trans-2,trans-13-dienoate were dissolved In 130 ml of a mixture of ethanol-water (3 1), mixed with 3.9 g of potassium hydroxide and stirred at 25°C for 2 hours. The reaction mixture was acidified with aqueous solution of oxalic acid to pH 5, and diluted with 100 ml of water, extracted with ethyl acetate. The extracts were washed with water, dried over sodium sulfate and concentrated under reduced pressure to obtain 3,88 g of 90 -hydroxy-11a,15a-bis-(2-tetrahydropyranyloxy)-16,16-dimethyl-prosta-trans-2,trans-13-dienoic acid. 

Synthesis of 16,16-dimethyl-trans-A -PGEi 2.35 g of the bis-tetrahydropyranyl ether were dissolved in 6 ml of tetrahydrofuran and 60 ml of 65%-acetic acid aqueous solution and the solution stirred at 60°C to 70°C for 20 minutes. The reaction mixture was extracted with ethyl acetate, and the organic layer was washed with water, dried and concentrated under reduced pressure. The residue was purified by column chromatography on silica gel using ethyl acetate-cyclohexane (2 3) as eluent to yield 270 mg of the title compound. 

Flash chromatography is widely employed for the purification of crude products obtained by synthesis at a research laboratory scale (several grams) or isolated as extracts from natural products or fermentations. The solid support is based on silica gel, and the mobile phase is usually a mixture of a hydrocarbon, such as hexane or heptane, with an organic modifier, e.g. ethyl acetate, driven by low pressure air. (Recently the comparison of flash chromatography with countercurrent chromatography (CCC), a technique particularly adapted to preparative purposes, has been studied for the separation of nonchiral compounds [90].)... 

In the first publication describing the preparative use of an enzymatic reaction in ionic liquids, Erbeldinger et al. reported the use of the protease thermolysin for the synthesis of the dipeptide Z-aspartame (Entry 6) [34]. The reaction rates were comparable to those found in conventional organic solvents such as ethyl acetate. Additionally, the enzyme stability was increased in the ionic liquid. The ionic liquid was recycled several times after the removal of non-converted substrates by extraction with water and product precipitation. Recycling of the enzyme has not been reported. It should be noted, however, that according to the log P concept described in the previous section, ethyl acetate - with a value of 0.68 - may interfere with the pro-... 

These procedures illustrate the use of N-ethyl-5-phenylisoxazolium-3 -sulfonate as a reagent for peptide synthesis.2-3 Procedure A is recommended for peptides that are not soluble in either organic solvents or in water. Procedure B illustrates the formation of a peptide that is soluble both in organic solvents and in water. Por peptides that are soluble in organic solvents and insoluble in water, the submitters recommend the use of Procedure B, except that the peptide product may be recovered directly from its solution in ethyl acetate after this organic solution has been washed successively with aqueous 5% sodium bicarbonate, water, aqueous 1 M hydrochloric acid, and water. Table I summarizes the preparation of various peptides by these procedures. Some more complex examples from other laboratories are listed elsewhere.2b... 

A solvent-free strategy for the synthesis of thiazoles involved mixing of thioamides with a-tosyloxy ketones in a clay-catalyzed reaction (Scheme 7). The typical procedure entailed mixing of thioamides and in situ produced a-tosyloxy ketones with montmorillonite K-10 clay in an open glass container. The reaction mixture was irradiated in a microwave oven for 2-5 min with intermittent irradiation and the product was extracted into ethyl acetate to afford 2-substituted thiazoles in 88-96% yields [8]. 

Linear non-cross-linked polystyrene has been used for organic synthesis since it is readily soluble in common organic solvents (i.e., dichloromethane, chloroform, tetrahydrofuran, toluene, ethyl acetate, and pyridine) but precipitates upon addition of water or methanol [123-126]. However, no examples of the use of this polymer in conjunction with microwave chemistry have been reported. 

The chemoenzymatic synthesis of the analgesic U-(—)-50,488 [41] and new C2-symmetric bisaminoamide ligands derived from N,N-disubstituted trans-cyclohexane, ,2-diamine [41] has been possible by a CALB-catalyzed resolution using ethyl acetate as solvent and acyl donor [42]. 

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