Conjugate acid formation

Conversely, we can reason that the formation of conjugate acids from bases will be favoured by electron-donating substituents and inhibited by electron-withdrawing groups. However, the feature of bases is that they have a lone pair of electrons that are able to coordinate with a proton. Sometimes, this lone pair may feed into the molecule via a resonance effect, and this can stabilize the free base and inhibit conjugate acid formation. With bases, therefore, we normally consider two approaches, either stabilization of the conjugate acid, which increases basicity, or stabilization of the free base, which decreases basicity. 

Elastic-collision model, Szilard-Chalmers reaction and, 268-269 Elastic-inelastic collision model, Szilard-Chalmers reaction and, 269 Electrolytes, sulfuric acid solutions, acids and, 400-403 acid-base reactions and, 403-405 anhydride formation and, 399 metal hydrogen sulfates and, 395-397 simple conjugate acid formation and, 397... 

Base is chosen so as to favor enolate formation. Acidity of C-H bond must be greater (lower pKa value) than that of the conjugate acid of the base (C S table 1.1, pg 3)... 

The formation of the above anions ("enolate type) depend on equilibria between the carbon compounds, the base, and the solvent. To ensure a substantial concentration of the anionic synthons in solution the pA" of both the conjugated acid of the base and of the solvent must be higher than the pAT -value of the carbon compound. Alkali hydroxides in water (p/T, 16), alkoxides in the corresponding alcohols (pAT, 20), sodium amide in liquid ammonia (pATj 35), dimsyl sodium in dimethyl sulfoxide (pAT, = 35), sodium hydride, lithium amides, or lithium alkyls in ether or hydrocarbon solvents (pAT, > 40) are common combinations used in synthesis. Sometimes the bases (e.g. methoxides, amides, lithium alkyls) react as nucleophiles, in other words they do not abstract a proton, but their anion undergoes addition and substitution reactions with the carbon compound. If such is the case, sterically hindered bases are employed. A few examples are given below (H.O. House, 1972 I. Kuwajima, 1976). 

The most important appHcation of metal alkoxides in reactions of the Friedel-Crafts type is that of aluminum phenoxide as a catalyst in phenol alkylation (205). Phenol is sufficientiy acidic to react with aluminum with the formation of (CgH O)2Al. Aluminum phenoxide, when dissolved in phenol, greatiy increases the acidic strength. It is beheved that, similar to alkoxoacids (206) an aluminum phenoxoacid is formed, which is a strong conjugate acid of the type HAl(OCgH )4. This acid is then the catalyticaHy active species (see Alkoxides, metal). 

The predominant, if not exclusive, formation of 5/7-fused hydroxy ketones was observed in the case of 4-alkylated dienones [(204) (205) (R = CH3) 6 1 from (201) (R = CH3)] ° and of prednisone 21-acetate [(206)-> (207)]. It appears therefore likely that intermediates which represent the conjugate acids of the postulated zwitterionic intermediates in the dienone photoisomerizations [c/. (202), (203)] participate both in the acid-catalyzed transformations of (200) and in the dienone photochemistry in protic solvents. 

Consider a nucleus that can partition between two magnetically nonequivalent sites. Examples would be protons or carbon atoms involved in cis-trans isomerization, rotation about the carbon—nitrogen atom in amides, proton exchange between solute and solvent or between two conjugate acid-base pairs, or molecular complex formation. In the NMR context the nucleus is said to undergo chemical exchange between the sites. Chemical exchange is a relaxation mechanism, because it is a means by which the nucleus in one site (state) is enabled to leave that state. 

In these papers, the carboxylic acid to be protected was a stable, unsubstituted compound. Harsh conditions were acceptable for both formation and cleavage of the amide. Typically, a simple secondary amide is very difficult to cleave. As the pKa of the conjugate acid of an amide decreases, the rate of hydrolysis of amides derived from these amines increases. The dimethylamide of a cephalosporin was prepared as follows using 2,2 -dipyridyl disulfide. ... 

As in the case of diazotization by N203 (Sec. 3.1), either the formation of XNO or the nitrosation of the amine (or of the aminium ion) may be rate-limiting. Under most experimental conditions the second alternative applies. If a steady-state concentration of XNO exists (which is however, not always the case) the reaction system of Schemes 3-26 and 3-27 yields the rate equation shown in Scheme 3-29 if it is the amine base (ArNH2) that is nitrosated. Xa is the acidity constant of the conjugate acid (ArNH3). 

C18-0013. Determine the mass of solid sodium formate (NaHC02) and the volume of 0.500 M HCl solution required to generate 250 mL of buffer solution with pH = 3.50 and a total concentration (conjugate acid plus base) of 0.225 M. 

C18-0095. The pH of a formic acid/formate buffer solution is 4.04. Calculate the acid/conjugate base ratio for this solution. Draw a molecular picture that shows a small region of the buffer solution. (You may omit spectator ions and water molecules.) Use the following symbols ... 

A base has the ability to donate a pair of electrons and an acid the ability to accept a pair of electrons to form a covalent bond. The product of a Lewis acid-base reaction may be called an adduct, a coordination compound or a coordination complex (Vander Werf, 1961). Neither salt nor conjugate acid-base formation is a requirement. 

The formation of the Wheland intermediate from the ion-radical pair as the critical reactive intermediate is common in both nitration and nitrosation processes. However, the contrasting reactivity trend in various nitrosation reactions with NO + (as well as the observation of substantial kinetic deuterium isotope effects) is ascribed to a rate-limiting deprotonation of the reversibly formed Wheland intermediate. In the case of aromatic nitration with NO, deprotonation is fast and occurs with no kinetic (deuterium) isotope effect. However, the nitrosoarenes (unlike their nitro counterparts) are excellent electron donors as judged by their low oxidation potentials as compared to parent arene.246 As a result, nitrosoarenes are also much better Bronsted bases249 than the corresponding nitro derivatives, and this marked distinction readily accounts for the large differentiation in the deprotonation rates of their respective conjugate acids (i.e., Wheland intermediates). 

The concentration of the conjugate acid is the rate-determining factor because it is the dissociation of that species that leads to the formation of the product. Therefore, the rate law can be written as... 

Alternatively, the translational energy threshold for endothermic proton transfer from MH+ to R can be measured using a flowing afterglow triple quadrupole instrument.127 These data define the proton affinity of M, relative to that of R. Thus, the PA of cyclopropenylidene was found to exceed that of ammonia by 23.3 1.8 kcal/mol (Table 6).128 In order to obtain absolute proton affinities, the enthalpies of formation of both the base and the conjugate acid must be known from other measurements (Eq. 9). Numerous reference compounds with known absolute PA are available.124... 

Few relevant data are available. Both equilibrium and rate constants have been measured for very few reaction series in solution, but comparisons are possible for lactone and thiolactone formation, and for a few anhydrideforming reactions (Tables 4 and 5). For lactone formation (Table 4) the EM for the rate process is of the same order of magnitude as that derived from the equilibrium constant data, and in some cases actually exceeds it (though only in one case by an amount clearly greater than the estimated uncertainty which is nominally a factor of 4 for these ratios). Lactonization generally involves rate-limiting breakdown of the tetrahedral intermediate, and the transition state is expected to be late and thus close in structure to the conjugate acid of the lactone. 

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