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Kinetic acidities of carbon acids

Recent developments include the measurement of the kinetic basicities of EGB s by convenient electroanalytical methods. The establishment of a scale of EGB basicities will in turn facilitate the measurement of kinetic acidities of carbon acids. [Pg.132]

Lahti, M. Kankaanpera, A. Virtanen, P. Kinetic acidity of carbon acids the hydroxide ion catalyzed ionization of chloroform and acetophenone in aqueous HMPA. /. Chem. [Pg.205]

For those compounds that do not establish acid-base equilibria rapidly, studies of rates of isotopic exchange can be used to determine relative kinetic acidities of carbon acids. For a discussion of the correlation of kinetic acidities with equilibrium acidities, see Streitwieser, A., Jr. Kaufman, M. J. Bors, D. A. Murdoch, J. R. MacArthur, C. A. Murphy, J. T. Shen, C. C. J. Am. Chem. Soc. 1985, 107, 6983 and references therein. [Pg.421]

Similarly, carboxylic acid and ester groups tend to direct chlorination to the / and v positions, because attack at the a position is electronically disfavored. The polar effect is attributed to the fact that the chlorine atom is an electrophilic species, and the relatively electron-poor carbon atom adjacent to an electron-withdrawing group is avoided. The effect of an electron-withdrawing substituent is to decrease the electron density at the potential radical site. Because the chlorine atom is highly reactive, the reaction would be expected to have a very early transition state, and this electrostatic effect predominates over the stabilizing substituent effect on the intermediate. The substituent effect dominates the kinetic selectivity of the reaction, and the relative stability of the radical intermediate has relatively little influence. [Pg.704]

The easiest access to most benzyllithium, -sodium, or -potassium derivatives consists of the deprotonation of the corresponding carbon acids. Hydrocarbons, such as toluene, exhibit a remarkably low kinetic acidity. Excess toluene (without further solvent) is converted into benzyllithium by the action of butyllithium in the presence of complexing diamines such as A. Af.Af.jV -tetramethylethylenediamine (TMEDA) or l,4-diazabicyclo[2.2.2]octane (DABCO) at elevated temperatures1 a procedure is published in reference 2. [Pg.189]

A kinetic study of nitration by nitric acid in carbon tetrachloride has been briefly reported and is of interest because of the third-order dependence of rate upon nitric acid concentration, for nitration of N-methyl-N-nitrosoaniline. This is believed to arise from equilibria (28) and (29) below, which give rise to a nitrosating species and nitration is achieved through subsequent oxidation of the nitrosated aromatic69. [Pg.35]

Kresge et a/.498 have drawn attention to the fact that detritiation of [3H]-2,4,6-trihydroxy- and [3H]-2,4,6-trimethoxy-benzenes by concentrated aqueous perchloric acid gives correlations of log rate coefficient with — H0 with slopes of 0.80 and 1.14 respectively. Protonation to give the carbon conjugate acids is, however, governed by h0lA0 and h0l 9S, respectively, which suggests that the difference in kinetic acidity dependence is a property of the substrate and should not be interpreted as a major difference in mechanism. The kinetic difference can be eliminated by an appropriate comparison of kinetic and equilibrium acidity dependencies. In equation (230)... [Pg.221]

The kinetic dependence of the reaction was explained in terms of a reaction between PhB(OH)3 and PhHg+. From analysis of the concentration of the species likely to be present in solution it was shown that reaction between these ions would yield an inverse dependence of rate upon molecular acid composition in buffer solutions, as observed for a tenfold change in molecular acid concentration, and that at high pH this dependence should disappear as found in carbonate buffers of pH 10. The form of the transition state could not be determined from the available data, and it would be useful to have kinetic parameters which might help to decide upon the likelihood of the 4-centre transition state, which was one suggested possibility. [Pg.363]

The first report of the use of bromine for the oxidation of sulphoxides appeared in 1966116. Diphenyl sulphone was isolated in 0.5-1% yield when the sulphoxide was treated with bromine in aqueous acetic acid for several hours. The yield was increased to about 5% by quenching the reaction with sodium carbonate. A kinetic study117 of a similar reaction involving dimethyl sulphoxide showed no significant yield improvement but postulated that the mechanism proceeds via an equilibrium step forming a bromosulph-onium type intermediate which reacted slowly with water giving dimethyl sulphone as indicated in equation (35). [Pg.981]

The auto-decomposition of lead tetraacetate in acetic acid, which normally occurs at reflux temperature , can be studied at 50 °C in the presence of sodium acetate The principal products of both the uncatalysed and catalysed decompositions are acetoxyacetic acid and carbon dioxide. The kinetic order of the normal decay of Pb(IV) is complex and evidence was obtained that oxidation of products is significant after the earliest stages. The evidence indicates that slow, simple homolytic breakage of lead tetraacetate to give Pb(OAc)3- and AcO-does not occur but that the solvent plays an integral part, e.g. [Pg.346]

Phosphonoformic acid (85) decarboxylated in acid solution, and it was proposed that the uncatalysed reaction involved a simple decarboxylation of the zwitterion. The acid-catalysed reaction showed some kinetic similarity to that of mesitoic acid and an elimination of carbon dioxide as trihydroxymethylcarbonium ion was preferred. Participation of the trans vicinal phosphonyl group in the solvolysis of the halides (86) and (87) has been deduced from rate measurements. In the norbornene derivatives, the relative rates of loss of chloride from (87a) and (87b) were 5 x 10 1. [Pg.114]

In this chapter, we have summarized (recent) progress in the mechanistic understanding of the oxidation of carbon monoxide, formic acid, methanol, and ethanol on transition metal (primarily Pt) electrodes. We have emphasized the surface science approach employing well-defined electrode surfaces, i.e., single crystals, in combination with surface-sensitive techniques (FTIR and online OEMS), kinetic modeling and first-principles DFT calculations. [Pg.197]

The reaction of cycloheptaamylose with diaryl carbonates and with diaryl methylphosphonates provides a system in which a carboxylic acid derivative can be directly compared with a structurally analogous organo-phosphorus compound (Brass and Bender, 1972). The alkaline hydrolysis of these materials proceeds in twro steps, each of which is associated with the appearance of one mole of phenol (Scheme Y). The relative rates of the two steps, however, are reversed. Whereas the alkaline hydrolysis of carbonate diesters proceeds with the release of two moles of phenol in a first-order process (kh > fca), the hydrolysis of methylphosphonate diesters proceeds with the release of only one mole of phenol to produce a relatively stable aryl methylphosphonate intermediate (fca > kb), In contrast, kinetically identical pathways are observed for the reaction of cycloheptaamylose with these different substrates—in both cases, two moles of phenol are released in a first-order process.3 Maximal catalytic rate constants for the appearance of phenol are presented in Table XI. Unlike the reaction of cycloheptaamylose with m- and with p-nitrophenyl methylphosphonate discussed earlier, the reaction of cycloheptaamylose with diaryl methylphosphonates... [Pg.240]

All preparations were structurally characterized by means of XRD (Siemens 5005). TEM imaging was performed with a Philips CM200 instrument. 27A1 and 29Si MAS NMR (Broker 500 MFlz and 360 MFlz respectively) was used to study the microporous phase and the kinetic of its formation. The relaxation delays were 0.2s and 200s respectively. Acidity was determined by the adsorption of carbon monoxide after activating the samples in vacuum (10 6 mbar) at 450°C for 1 h. The spectra were recorded on a Equinox 55 Broker spectrometer with a resolution of 2 cm 1 and normalized to 10 mg of sample. [Pg.94]

The only dependencies noted in the kinetic studies were first-order dependencies on iodide promoter and rhodium concentrations. Thus there was no observed effect of varying methanol concentration, and the partial pressure of carbon monoxide had no effect on the reaction rate. Similarly, the concentration of the products, methyl acetate and acetic acid, has no effect on the reaction rate. Thus we have the unusual situation of a reaction, CH3OH + CO — CH3COzH, in which the concentrations of the reactants and product have no kinetic influence. [Pg.257]

The attack of carbon nucleophiles such as Grignard reagents [116, 235, 236], cuprates [183, 237-242] and C-H acidic compounds [212] on allenes 155 leads generally to the non-conjugated products 158. However, it was observed early that 158 is the product of a kinetically controlled reaction also in these cases, whereas the thermodynamically more stable product 159 is formed at longer reaction times or subse-... [Pg.382]


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See also in sourсe #XX -- [ Pg.77 , Pg.80 , Pg.81 ]




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