Steric effects base-catalyzed

A direct comparison of the stereochemical efficiency of the fragmentation reaction versus the tandem reaction (Scheme 53) was studied by Porter et al. as a function of the steric effect based on the Taft parameters for different substituents [146]. In general, the tandem reactions perform better and provide higher levels of ee s than the fragmentation reactions. This effect could be due to the tinbromide by-product catalyzing a non-stereoselective process as has been uncovered by the same authors (vide supra) and by Sibi and Ji in their diastereoselective studies [147]. 

The azo coupling reaction proceeds by the electrophilic aromatic substitution mechanism. In the case of 4-chlorobenzenediazonium compound with l-naphthol-4-sulfonic acid [84-87-7] the reaction is not base-catalyzed, but that with l-naphthol-3-sulfonic acid and 2-naphthol-8-sulfonic acid [92-40-0] is moderately and strongly base-catalyzed, respectively. The different rates of reaction agree with kinetic studies of hydrogen isotope effects in coupling components. The magnitude of the isotope effect increases with increased steric hindrance at the coupler reaction site. The addition of bases, even if pH is not changed, can affect the reaction rate. In polar aprotic media, reaction rate is different with alkyl-ammonium ions. Cationic, anionic, and nonionic surfactants can also influence the reaction rate (27). 

Fundamental to the interpretations of cr as a measure of electronic effects is the validity of the assumption that the steric effect is identical in acid- and base-catalyzed... 

Recently, Porter et al. (1986b, 1988) have reported the synthesis of both meso- and ( )-forms of a series of two-chain carbonyl diacids made by joining two pentadecanoic acid units by a carbonyl group at the 3,3, 6,6, 9,9 and 12,12 positions, 3,5-didodecyl-4-oxoheptanedioic acid (C-15 3,3 ), 6,8-dinonyl-7-oxotridecanedioic acid (C-15 6,6 ), 9,11-dihexyl-10-oxononadecanedioic acid (C-15 9,9 ) and 12,14-dipropyl-13-oxopentacosanedioic acid (C-15 12,12 ), respectively. The diacids were used to probe further the question of stereochemical preference in two-chain amphiphiles. The method used for examining the diastereomeric preference was equilibration by base-catalyzed epimerization in homogeneous, bilayer and micellar media. This method allows for stereoselection based on hydrophobic/hydrophilic considerations rather than classic steric size effects. 

The hydrogenations become analogous to those involving HMn(CO)5 (see Section II,D), and to some catalyzed by HCo(CN)53 (see below). Use of bis(dimethylglyoximato)cobalt(II)-base complexes or cobaloximes(II) as catalysts (7, p. 193) has been more thoroughly studied (189, 190). Alkyl intermediates have been isolated with some activated olefinic substrates using the pyridine system, and electronic and steric effects on the catalytic hydrogenation rates have been reported (189). Mechanistic studies have appeared on the use of (pyridine)cobaloxime(II) with H2, and of (pyridine)chlorocobaloxime(III) and vitamin B12 with borohydride, for reduction of a,/3-unsaturated esters (190). Protonation of a carbanion... 

Taft based his steric effect constants on the assumption that rates of esterification of carboxylic acids with alcohols and of acid catalyzed hydrolysis of carboxylate... 

Taft, following Ingold,39 assumed that for the hydrolysis of carboxylic esters, steric and resonance effects will be the same whether the hydrolysis is catalyzed by acid or base (see the discussion of ester-hydrolysis mechanisms, reaction 0-10). Rate differences would therefore be caused only by the field effects of R and R in RCOOR. This is presumably a good system to use for this purpose because the transition state for acid-catalyzed hydrolysis (7) has a greater positive charge (and is hence destabilized by - / and stabilized by + / substituents) than the starting ester, while the transition state for base-catalyzed hydrolysis (8)... 

Abstract—A review of the literature is presented for the hydrolysis of alkoxysilane esters and for the condensation of silanols in solution or with surfaces. Studies using mono-, di-, and trifunctional silane esters and silanols with different alkyl substituents are used to discuss the steric and electronic effects of alkyl substitution on the reaction rates and kinetics. The influences of acids, bases, pH, solvent, and temperature on the reaction kinetics are examined. Using these rate data. Taft equations and Brensied plots are constructed and then used to discuss the mechanisms for acid and base-catalyzed hydrolysis of silane esters and condensation of silanols. Practical implications for using organofunctional silane esters and silanols in industrial applications are presented. 

Now that the steric parameter can be evaluated, the inductive parameter is available. Taft noted that the transition-state structures for acid- and base-catalyzed hydrolysis of esters (15 and 16, respectively) differ from each other by only tiny protons. Therefore the steric effect of a substituent should be approx-... 

Hydrolysis reactions involving tetrahedral intermediates are subject to steric and electronic effects. Electron-withdrawing substituents facilitate, but electron-donating and bulky substituents retard basic hydrolysis. Steric effects in acid-catalyzed hydrolysis are similar to those in base-catalyzed hydrolysis, but electronic effects are much less important in acid-catalyzed reactions. Higher temperatures also accelerate the reaction. 

Because the electronic nature of substituents has little effect on the rate of acid-catalyzed hydrolysis of meta- or para-substituted benzoates (e.g., p for the acid hydrolysis of XC6H4COOR esters is close to zero), Taft suggested that the electronic nature of substituents will also have little effect on acid-catalyzed hydrolysis of aliphatic esters (Lowry and Richardson, 1987). Nevertheless, a strong electronic effect occurs in basic hydrolysis, as can be examined from the large p values for base-catalyzed hydrolysis of meta- or para-substituented benzoates. Hence, the effect of X on acid hydrolysis is purely steric but is a combination of steric and electronic effects in basic hydrolysis. Taft defined Es, a steric substituent constant, by Equation (5.11) ... 

Hydrogen exchange can occur under either acid- or base-catalyzed conditions. Both can be considered electrophilic aromatic substitutions, the latter involving attack of the electrophile upon an aromatic anion, zwitterion, or ylide. The former reaction is aided by electron supply, the latter by electron withdrawal (particularly by -/ effects) as the ratedetermining step is the initial proton loss. Steric hindrance, negligible in virtually all cases under acid-catalyzed conditions, appears to be of slightly greater importance under base-catalyzed conditions. 

Since the base must attack the ring hydrogens in the plane of the ring, but away from it, one would expect steric effects to be minimal, and certainly no more than for acid-catalyzed exchange. This appears to be the case for attack by amide, but the bulkier cyclohexylamide shows evidence of some steric hindrance [72MI2(266)]. 

An oxygen function in the 4-position of a tetrahydroisoquinoline is benzylic and in a ring. On the basis of its electronic and steric situation, it should be, and is, readily replaced by nucleophiles. The nucleophiles which have been found to be effective thus far are activated (by oxygen) aromatic rings and alcohols. In a related reaction, 4,7-diacetoxytetra-hydroisoquinolines have been shown to undergo a number of base-catalyzed nucleophilic reactions. 

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