Tetraethylammonium bromide, effect

Irons-Testosterone, as metabolite of testosterone, X, 258 Testosterone propionate, cortisone and, IX, 274 effect on retention of chloride, VI, 313 of sodium, VI, 313 Tetraethylammonium bromide, effect in hypertensive toxemia, X, 171... 

The salt effects of potassium bromide and a series office symmetrical tetraalkylammonium bromides on vapor-liquid equilibrium at constant pressure in various ethanol-water mixtures were determined. For these systems, the composition of the binary solvent was held constant while the dependence of the equilibrium vapor composition on salt concentration was investigated these studies were done at various fixed compositions of the mixed solvent. Good agreement with the equation of Furter and Johnson was observed for the salts exhibiting either mainly electrostrictive or mainly hydrophobic behavior however, the correlation was unsatisfactory in the case of the one salt (tetraethylammonium bromide) where these two types of solute-solvent interactions were in close competition. The transition from salting out of the ethanol to salting in, observed as the tetraalkylammonium salt series is ascended, was interpreted in terms of the solute-solvent interactions as related to physical properties of the system components, particularly solubilities and surface tensions. 

An examination of Figures 1-6 indicates that Equation 1 is valid under conditions of constant x for potassium, ammonium, and tetramethylammonium bromides in ethanol-water mixtures. All three salts show an ability to salt out ethanol from these mixtures (i.e., increase its concentration in the equilibrium vapor) which is verified by their k values shown in Table XVIII. Also, the results for tetra-n-propylammonium bromide and tetra-n-butylammonium bromide in ethanol-water mixtures reveal that Equation 1 can be used to predict the salt effects of these systems however, these two salts demonstrate a propensity to salt in ethanol (i.e., decrease its vapor concentration) in ethanol-water mixtures. On the other hand, Figures 7-9 and the data in Table XVIII reveal that Equation 1 cannot be used to correlate the salt effects of tetraethylammonium bromide in ethanol-water. For this system, a linear dependence of log aja vs. z is observed initially however, a gradual levelling off occurs at higher concentrations. 

Tetraethylammonium bromide is much less reactive than the chloride, and tetraethylammonium fluoride trihydrate is unreactive which has been attributed to the effect of water in reducing the nucleophilicity of the fluoride ion in nonaqueous solutions.17 The allylie rearrangement of chlorine in cyclobutene 13 has been reported to be catalyzed by triethylamine.63... 

Potassium ert-butoxide, sodium hydride, butyllithium have all been used for this purpose. The alkyl(aryl)sulfanylcarbene (carbenoid) thus generated undergoes addition, often effectively, across the double bond of alkenes, enol ethers, ketene acetals and enamines. The use of chloromethyl phenyl sulfide, oxirane, tetraethylammonium bromide as a catalyst and an alkene gave phenylsulfanylcyclopropanes in rather low yield. For the synthesis of l,l-dimethyl-2-phenylsulfanylcyclopropane, see Houben-Weyl, Vol.4/3, p250 and of endoj exo-7-phenylsulfanylbicyclo[4.1.0]heptane, see Vol. E19b, pl691. 

N-Alkylation of -lactams. This reaction can be carried out readily under phase-transfer conditions. Tetra-n-butylamnlonium bromide is somewhat more effective than tetraethylammonium bromide or benzyltriethylammonium chloride. ... 

The scheme of the peroxides activation and decomposition in the presence of quaternary onium salt is proposed. It is substantiated by kinetic methods as well as by molecular modeling methods. It has been shown that peroxides decomposition in the presence of tetraethylammonium bromide proceeded according to supramolecular mechanism. Cyclohexanone peroxides in the presence of Et4NBr effectively initiate the radical chain cumene oxidation. 

Figure 2. Dependence of effective rate constant of a - oxycyclohexylhydroperoxide (a) and a,a -dioxydicyclohexylperoxide (b) decomposition activated by tetraethylammonium bromide upon Et4N Br concentration ([R OOR ]o = 510 M T, K 1 - 323,2 - 333, 3 - 343,4 - 353).

As expected, HTMAB made a respectable showing in these experiments. Trioctylmethylammonium chloride (TOMAC) and trioctylmetliylammonium bromide (TOMAB) outperformed all other catalysts. It was postulated that the three octyl groups were the proper length for solvation of the polymer while at the same time small enough to avoid sterically hindering the reaction. In order to determine if TOMAB could be used to catalyze PET depolymerization for more than one treatment cycle, the catalyst was recovered upon completion of one treatment and added to a second run for 60 min. Tetraethylammonium hydroxide (TEAOH) was studied as a catalyst in order to demonstrate the effect of hydroxide ion as a counterion. The percent PET conversion for the second cycle was 85.7% compared to a conversion of 90.4% for the first treatment cycle. 

Fluoride ion is effective in promoting the reduction of aldehydes by organosil-icon hydrides (Eq. 161). The source of fluoride ion is important to the efficiency of reduction. Triethylsilane reduces benzaldehyde to triethylbenzyloxysilane in 36% yield within 10-12 hours in anhydrous acetonitrile solvent at room temperature when tetraethylammonium fluoride (TEAF) is used as the fluoride ion source and in 96% yield when cesium fluoride is used.83 The carbonyl functions of both p-anisaldehyde and cinnamaldehyde are reduced under similar conditions. Potassium bromide or chloride, or tetramethylammonium bromide or chloride are not effective at promoting similar behavior under these reaction conditions.83 Moderate yields of alcohols are obtained by the KF-catalyzed PMHS, (EtO SiH, or Me(EtO)2SiH reduction of aldehydes.80,83,79... 

The data in Tables I-XVI (see Appendix for all tables) show the isobaric vapor-liquid equilibrium results at the boiling point for potassium, ammonium, tetramethylammonium, tetraethylammonium, tetra-n-propylammonium, and tetra-n-butylammonium bromides in various ethanol-water mixtures at fixed liquid composition ratios. The temperature, t, is the boiling temperature for all solutions in these tables. In all cases, the ethanol-water composition was held constant between 0.20 and 0.35 mole fraction ethanol since it is in this range that the most dramatic salt effects on vapor-liquid equilibrium in this particular system should be observed. That is, previous data (12-15,38) have demonstrated that a maximum displacement of the vapor-liquid equilibrium curve by salts frequently occurs in this region. In the results presented here, it should be noted that Equation 1 has been modified to... 

Stoichiometric amounts of tetraethylammonium cyanide react with aliphatic bromides in dichloromethane, acetonitrile or DMSO to give reasonable yields of the corresponding nitriles [13]. These reactions are clearly related to, but not actually examples of, phase transfer catalysis. It is interesting, however, that under these homogeneous conditions, tetraethylammonium cyanide reacts in acetonitrile with neopentyl bromide to give the corresponding nitrile (see Eq. 7.3). Bimolecular displacements on such sterically hindered substrates are usually quite difficult to effect. 

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