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Specific acid catalysi

Pos twe-Tone Photoresists. The ester, carbonate, and ketal acidolysis reactions which form the basis of most positive tone CA resists are thought to proceed under specific acid catalysis (62). In this mechanism, illustrated in Figure 22 for the hydrolysis of tert-huty acetate (type A l) (63), the first step involves a rapid equihbrium where the proton is transferred between the photogenerated acid and the acid-labile protecting group ... [Pg.126]

The sulfonated resin is a close analogue of -toluenesulfonic acid in terms of stmcture and catalyst performance. In the presence of excess water, the SO H groups are dissociated, and specific acid catalysis takes place in the swelled resin just as it takes place in an aqueous solution. When the catalyst is used with weakly polar reactants or with concentrations of polar reactants that are too low to cause dissociation of the acid groups, general acid catalysis prevails and water is a strong reaction inhibitor (63). [Pg.175]

The role that acid and base catalysts play can be quantitatively studied by kinetic techniques. It is possible to recognize several distinct types of catalysis by acids and bases. The term specie acid catalysis is used when the reaction rate is dependent on the equilibrium for protonation of the reactant. This type of catalysis is independent of the concentration and specific structure of the various proton donors present in solution. Specific acid catalysis is governed by the hydrogen-ion concentration (pH) of the solution. For example, for a series of reactions in an aqueous buffer system, flie rate of flie reaction would be a fimetion of the pH, but not of the concentration or identity of the acidic and basic components of the buffer. The kinetic expression for any such reaction will include a term for hydrogen-ion concentration, [H+]. The term general acid catalysis is used when the nature and concentration of proton donors present in solution affect the reaction rate. The kinetic expression for such a reaction will include a term for each of the potential proton donors that acts as a catalyst. The terms specific base catalysis and general base catalysis apply in the same way to base-catalyzed reactions. [Pg.229]

The experimental detection of general acid catafysis is done by rate measurements at constant pH but differing buffer concentration. Because under these circumstances [H+] is constant but the weak acid component(s) of the buffer (HA, HA, etc.) changes, the observation of a change in rate is evidence of general acid catalysis. If the rate remains constant, the reaction exhibits specific acid catalysis. Similarly, general base-catalyzed reactions show a dependence of the rate on the concentration and identity of the basic constituents of the buffer system. [Pg.229]

Specific acid catalysis is observed when a reaction proceeds through a protonated intermediate that is in equilibrium with its conjugate base. Because the position of this equilibrium is a function of the concentration of solvated protons, only a single acid-dependent term appears in the kinetic expression. For example, in a two-step reaction involving rate-determining reaction of one reagent with the conjugate acid of a second, the kinetic expression will be as follows ... [Pg.230]

Notice that specific acid catalysis describes a situation in which the reactant is in equilibrium with regard to proton transfer, and proton transfer is not rate-determining. On the other hand, each case that leads to general acid catalysis involves proton transfer in the rate-determining step. Because of these differences, the study of rates as a function of pH and buffer concentrations can permit conclusions about the nature of proton-transfer processes and their relationship to the rate-determining step in a reaction. [Pg.230]

Both specific acid catalysis and general acid catalysis can be observed. (Review Section 4.8 for the discussion of specific and general acid catalysis.)... [Pg.451]

Specific acid catalysis is catalysis by the hydronium ion (in water) or the lyonium ion in general. Acid-catalyzed ester hydrolysis is an example. [Pg.264]

It is important for acid-catalysed reactions to determine whether the reaction is specifically catalysed by hydrogen ions or whether general acid catalysis takes place. Specific acid catalysis has been conclusively demonstrated for the benzidine rearrangement by three different sorts of kinetic experiments. In the first, it has been shown41 by the standard test for general acid catalysis (by measuring the rate of reaction in a buffered solution at constant pH over a range of concentration... [Pg.440]

The kinetic data based on the demonstration of specific acid catalysis in buffers, solvent isotope effects and acidity functions all support mechanisms where the proton-transfers are fast. It is possible to write equations which accommodate these facts together with the first-order dependence on hydrazo-compound and the concurrent first and second-order dependence on acidity. These are... [Pg.442]

This scheme requires a rate-determining (second) proton-transfer, against which there is considerable experimental evidence in the form of specific-acid catalysis, the solvent isotope effect and the hg dependence discussed earlier. Further, application of the steady-state principle to the 7i-complex mechanism results in a rate equation of the form... [Pg.446]

The reaction shows only specific acid catalysis under this condition. Even if acids other than H+ are present, they will alter the velocity only insofar as they change [H+]. That is, the concentration of the reactive species, [AH1 ], depends only upon [H+], irrespective of the acids that supply it. [Pg.237]

Specific acid catalysis. Derive an expression for the minimum rate constant along the pH profile in terms of kw, oh> o> and Kw. [Pg.249]

Finally, we should also exploit one more key experimental fact—the I activation barrier for the dissociation of the R-O bond in the protonated R-OH+R molecule is available from kinetic studies of the so-called 1 specific acid catalysis reaction. [Pg.163]

A knowledge of whether a reaction is subject to general or specific acid catalysis supplies information about the mechanism. For any acid-catalyzed reaction we can write... [Pg.338]

As enzymes work best near neutral pH, where only general acid catalysis is possible, the problem of general vs. specific acid catalysis deserves special... [Pg.321]

To account for the effects of specific acid catalysis, the calculations were also carried out in the presence of an additional proton. The resulting potential energy surface at PCM-B 3LYP/6-311 G(2df,p)//B 3LYP/6-31 G(d, p) level of theory suggested that the p-O-4-linked quinone methide ((3-O-QM) is a fairly stable species and its... [Pg.62]

When the drug is nonionizable in water, three hydrolytic pathways are available [Eq. (33)] it can degrade by specific acid catalysis represented by the first kinetic term in Eq. (33), water hydrolysis (second term), and specific base catalysis (third term) ... [Pg.160]

ALEXANDER D. RYABOV AND TERRENCE J. COLLINS III. Kinetics and Mechanisms of Demetalation of Fem-TAML Activators A. Specific Acid Catalysis... [Pg.478]

The term acid catalysis is often taken to mean proton catalysis ( specific acid catalysis ) in contrast to general acid catalysis. In this sense, acid-catalyzed hydrolysis begins with protonation of the carbonyl O-atom, which renders the carbonyl C-atom more susceptible to nucleophilic attack. The reaction continues as depicted in Fig. 7. l.a (Pathway a) with hydration of the car-bonium ion to form a tetrahedral intermediate. This is followed by acyl cleavage (heterolytic cleavage of the acyl-0 bond). Pathway b presents an mechanism that can be observed in the presence of concentrated inorganic acids, but which appears irrelevant to hydrolysis under physiological conditions. The same is true for another mechanism of alkyl cleavage not shown in Fig. 7.Fa. All mechanisms of proton-catalyzed ester hydrolysis are reversible. [Pg.384]

Fig. 7.1. a) Specific acid catalysis (proton catalysis) with acyl cleavage in ester hydrolysis. Pathway a is the common mechanism involving a tetrahedral intermediate. Pathway b is SN1 mechanism observed in the presence of concentrated inorganic acids. Not shown here is a mechanism of alkyl cleavage, which can also be observed in the presence of concentrated inorganic acids, b) Schematic mechanism of general acid catalysis in ester hydrolysis. [Pg.385]

See other pages where Specific acid catalysi is mentioned: [Pg.162]    [Pg.162]    [Pg.229]    [Pg.453]    [Pg.477]    [Pg.488]    [Pg.219]    [Pg.268]    [Pg.349]    [Pg.4]    [Pg.221]    [Pg.288]    [Pg.318]    [Pg.319]    [Pg.137]    [Pg.337]    [Pg.380]    [Pg.74]    [Pg.209]    [Pg.221]    [Pg.224]    [Pg.471]    [Pg.48]    [Pg.149]   
See also in sourсe #XX -- [ Pg.113 ]



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