Dioxan effect esters

Y. Takegami et al. [858] studied the effects of other solvents in this respect. They took toluene as a standard solvent in the propylene hydroformylation (n-aldehyde 77-73%). Compared to toluene, dioxane and esters such as butylacetate e.g. gave higher n/iso-ratios (n-aldehyde 83 to 79%) while acetone and diethyl ether increased the formation of the branched isomer (n-aldehyde 66-60%). 

Studies of reaction mechanisms ia O-enriched water show the foUowiag cleavage of dialkyl sulfates is primarily at the C—O bond under alkaline and acid conditions, and monoalkyl sulfates cleave at the C—O bond under alkaline conditions and at the S—O bond under acid conditions (45,54). An optically active half ester (j -butyl sulfate [3004-76-0]) hydroly2es at 100°C with iaversion under alkaline conditions and with retention plus some racemization under acid conditions (55). Effects of solvent and substituted stmcture have been studied, with moist dioxane giving marked rate enhancement (44,56,57). Hydrolysis of monophenyl sulfate [4074-56-0] has been similarly examined (58). 

The Tcrom ester is prepared from the cesium salt of an N-protected amino acid by reaction with 2-(trifluoromethyl)-6-chromylmethyl bromide (DMF, 25°, 4 h, 53-89% yield). Cleavage of the Tcrom group is effected by brief treatment with n-propylamine (2 min, 25°, 96% yield). It is stable to HCl/dioxane, used to cleave a BOC group. ... 

Some authors use O] instead of cr as the substituent constant in such correlations.) An example is provided by the aminolysis of phenyl esters in dioxane the substrates RCOOPh were reacted with -butylamine, and the observed first-order rate constants were related to amine concentration by = k2 [amine] kj [amine]. The rate constants kz and k could be correlated by means of Eq. (7-54), the reaction constants being p = +2.14, b = + 1.03 (for A 2) and p = -1-3.03,8 = -1-1.08 (for ks). Thus, the two reactions are about equally sensitive to steric effects, whereas the amine-catalyzed reaction is more susceptible to electronic effects than is the uncatalyzed reaction. 

Muller et al.understand better the role of tyrosine in the structure and biological function of MDH. Resolution of the protein absorption spectrum, using iV-acetylphenylalanine ethyl ester in dioxane and A-acetyltyrosine ethyl ester in dioxane or 0.1 M phosphate buffer to model the effect of the local environments of the chromophoric groups, indicated that both the pig and the... 

Diethyl ether has been shown to enhance decarboxylation [32] as a secondary reaction after C—O bond cleavage when the ortho and para positions are blocked. Scheme 7 shows this effect for compound 17. Some esters with the ortho and para positions free to react but with bulky substiments at the meta position also undergo decarboxylation in ether, tetrahydrofuran, and dioxane [33,34],... 

The solvents most commonly employed are water, ethyl and methyl alcohol, ether, benzene, petroleum ether, acetone, glacial acetic acid also two or three solvents may be mixed to get the desired effect as described later. If you still cannot dissolve the compound, try some of these chloroform, carbon disulfide, carbon tetrachloride, ethyl acetate, pyridine, hydrochloric acid, sulfuric acid (acids are usually diluted first), nitrobenzene, aniline, phenol, dioxan, ethylene dichloride, di, tri, tetrachloroethylene, tetrachloroethane, dichloroethyl ether, cyclohexane, cyclohexanol, tetralin, decalin, triacetin, ethylene glycol and its esters and ethers, butyl alcohol, diacetone alcohol, ethyl lactate, isopropyl ether, etc. 

Fig. 16. Effect of degree of crosslinking (% DVB) of standard (non-porous) ion exchanger on initial transesterification rate, r° (mol kg-1 h-1), of ethyl acetate with 1-propanol [436]. (1) Liquid phase at 52°C initial composition (mole%), 0.4 ethyl acetate, 0.4 1-propanol, 0.2 dioxan (solvent). (2) Vapour phase at 120°C partial pressure of reactants, 0.5 bar (ester—alcohol ratio 1 1).

Another approach attempts to explain the different effect of the ester structure in different reaction media simply by the changing ability of the esters to be absorbed by the resin. Qualitatively, this approach was used [476] to interpret the results for water and aqueous acetone and a similar idea was suggested for the hydrolysis of dicarboxylic acid esters in water—dioxan mixtures [482,483]. Quantitative interpretation was based [481,489] on Helfferich s model [427]. It follows from eqn. (30) and from the relation... 

A rather similar result has been obtained much more recently by Sadek et a/.108. These authors carried out a detailed investigation of the hydrolysis of benzyl acetate in aqueous dioxan, varying the solvent composition, and also the temperature (from 25 to 45°C). In the low-acidity region used (0.05 M HC1) the ester is hydrolyzed by the Aac2 mechanism, and the solvent effects are probably typical. The rate of hydrolysis decreases steadily as the proportion of dioxan in the medium is increased, as a result of a steady increase in AH, which is only partially offset by an increasingly favourable entropy of activation. However, the increase in AS1 eventually levels out at about 70% w/w dioxan, as illustrated by the data for 30°C ... 

In this work the rates of alkaline hydrolysis in 70% dioxan-water and those of acid-catalyzed ester formation in methanol were compared for the cis (31a) and trans (31b) substituted compounds. This was expected to isolate the steric effects of the cis substituents, since inductive and resonance effects should be similar in the cis and the trans compounds. The results are summarized in Table 34, and show the trend already observed for orf/m-substituted... 

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