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Acid attack hydrolysis

Factors other tlian tire Si/Al ratio are also important. The alkali-fonn of zeolites, for instance, is per se not susceptible to hydrolysis of tire Al-0 bond by steam or acid attack. The concurrent ion exchange for protons, however, creates Bronsted acid sites whose AlO tetraliedron can be hydrolysed (e.g. leading to complete dissolution of NaA zeolite in acidic aqueous solutions). [Pg.2787]

Acetals are usually liquid they are almost unaffected by alkalis and are not attacked by metallic sodium nor by Fehling s solution. They are identified by reference to the alcohol and aldehyde (or ketone if a ketal) which they yield when hydrolysed in acid solution. Hydrolysis proceeds readily in dilute acid solution e.g., with 3-5 per cent, acid). ... [Pg.327]

Castor oil sulfation results largely in a sulfuric acid ester in which the hydroxyl group of ricinoleic acid has been esterified. However, other reactions can also take place. For example, the double bond can be attacked to produce an ester or the hydroxysulfonic acid (33). Hydrolysis of the sulfuric acid esters occurs during the reaction and subsequent treatment forming hydroxy acids and sulfuric acid. These hydroxy acids can be further sulfated. [Pg.154]

The mechanism for acid-catalyzed hydrolysis of amides involves attack by water on the protonated amide. An inqjortant feature of the chemistry of amides is that the most basic site in an amide is the carbonyl oxygen. Very little of the N-protonated form is present. The major factor that contributes to the stability of the O-protonated form is the... [Pg.482]

Taft began the LFER attack on steric effects as part of his separation of electronic and steric effects in aliphatic compounds, which is discussed in Section 7.3. For our present purposes we abstract from that treatment the portion relevant to aromatic substrates. Hammett p values for alkaline ester hydrolysis are in the range +2.2 to +2.8, whereas for acid ester hydrolysis p is close to zero (see Table 7-2). Taft, therefore, concluded that electronic effects of substituents are much greater in the alkaline than in the acid series and. in fact, that they are negligible in the acid series. This left the steric effect alone controlling relative reactivity in the acid series. A steric substituent constant was defined [by analogy with the definition of cr in Eq. (7-22)] by Eq. (7-43), where k is the rate constant for acid-catalyzed hydrolysis of an orr/to-substituted benzoate ester and k is the corresponding rate constant for the on/to-methyl ester note that CH3, not H, is the reference substituent. ... [Pg.335]

Conversion of Acid Halides into Acids Hydrolysis Acid chlorides react with water to yield carboxylic acids. This hydrolysis reaction is a typical nucleophilic acyl substitution process and is initiated by attack of water on the acid chloride carbonyl group. The tetrahedral intermediate undergoes elimination of Cl and loss of H+ fo give the product carboxylic acid plus HC1. [Pg.802]

A similar case of enolatc-controlled stereochemistry is found in aldol additions of the chiral acetate 2-hydroxy-2.2-triphenylethyl acetate (HYTRA) when both enantiomers of double deprotonated (R)- and (S)-HYTRA are combined with an enantiomerically pure aldehyde, e.g., (7 )-3-benzyloxybutanal. As in the case of achiral aldehydes, the deprotonated (tf)-HYTRA also attacks (independent of the chirality of the substrate) mainly from the /te-side to give predominantly the t/nii-carboxylic acid after hydrolysis. On the other hand, the (S)-reagcnt attacks the (/ )-aldebyde preferably from the. S7-side to give. s wz-carboxylic acids with comparable selectivity 6... [Pg.574]

The basicities of some phosphinamides (84) have been measured and the acid-catalysed hydrolysis studied. Unsubstituted and A -alkyl derivatives follow an A2 mechanism of reversible protonation followed by ratedetermining water attack. However, the rates for the A -aryl derivatives follow Hq (but with a slope of 0.5), and an A mechanism was suggested as most consistent with this fact and the solvent isotope effect. The anomalous dependence on Ho, together with the large negative value of A5, while not necessarily excluding an ionization mechanism, leaves the question in some doubt. [Pg.114]

The p value for base-catalysed hydrolysis (+2-51) is +ve and quite large, reflecting the development of not inconsiderable -ve charge at the reaction centre in the rate-limiting step—attack on this centre by OH (step CD in the BAC2 pathway). By contrast, the p value for acid-catalysed hydrolysis (+0-03) is very nearly zero which means, of course, that the rate of this hydrolysis does not vary significantly from one ester to another, no matter what the m- or... [Pg.384]

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]

The sequence can be rationalized mechanistically as involving nucleophilic attack of ammonia onto the aldehyde to produce an imine, which then acts as the electrophile for further nucleophilic attack, this time by the cyanide ion (see Section 7.7.1). The racemic amino acid is then formed by acid-catalysed hydrolysis of the nitrile function, as above (Box 7.9). [Pg.245]

Examples of nucleophilic attack at the saturated 2-carbon of dihydro-l,4-thiazines, which may be assisted by the neighboring sulfur atom, are shown below. The nucleophiles include water, which was used in the acid-catalyzed hydrolysis of the ketal in 236 (Equation 21) <1982S424>, methanol in the conversion of 214 into a monothioacetal (Equation 22) <1982JHC131>, ethanol and dimethylaniline, which both reacted with 237 (Scheme 29) <1982TL4963>, and triethyl phosphite that was used to convert 238 into the phosphonate 239 required for Wadsworth-Emmons reaction (Equation 23) <2004BML1477>. Compound 240 reacted with both methanol and methanethiol (Equation 24) <1990JME1898>. [Pg.636]

Acid-catalyzed hydrolysis of the imidazo[4,5-f]isoxazole leads to the the two isoxazole monocyclic compounds, 40 and 41 (Equation 6), presumably via nucleophilic attack of water at the imidazole carbon atom <1999J(P1)817>. [Pg.168]

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See also in sourсe #XX -- [ Pg.604 ]



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Hydrolysis attack

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