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Nucleophilic attack activation parameters

However, an alternative mechanism by which CO is displaced by the nucleophilic attack of solvent was not excluded by these kinetics results, especially given that the activation parameters AH - 16.0 1.7 kcal/mol and AS - -1.9 3.0 cal mol" K - - for k0 s(limiting)... [Pg.139]

Analysis of the data allows the observation that the substrate/nucleophile association (Kc values, see Table 2) is clearly decreased on increasing the temperature, while the k and k 0 of Scheme 16 (the attack of the DBU on the free TNB and on the complexed TNB, respectively) are increased on increasing the temperature, showing activation parameters usual in S Ar reactions. [Pg.468]

Ashby and Yu have studied the kinetics of reduction of benzophenone with TIBA in ether and showed that the overall kinetic rate expression is second order, first order in TIBA and first order in ketone (151). The observed activation parameters were AG - 18.8 kcal/mol AH = 15.8 kcal/mol and AS = - 10.1 e.u. The negative entropy of activation is consistent with a cyclic transition state for the rate-determining hydride-transfer step. A Hammett study gave a value of p = 0.362, supporting nucleophilic attack by the aluminum alkyl on the carbonyl group in the rate-determining step. [Pg.291]

Nitrosyl complexes, in which Vno > 1886 cm or Fnq > 13.8 mdyn/A, usually react as electrophilic nitrosating agents so that the ligand can be considered NO [26]. Nucleophilic attack on the nitrosyl nitrogen is a common reaction encountered in the chemistry of nitroprusside and the rates and activation parameters for a number of different nucleophiles are listed in Table 3. Hydr-oxylamine adducts to nitroprusside via a rate law that is first order in the complex, the ligand and hydroxide (k = 4.5 x 10 M s ). [Pg.167]

The trends in the gas-phase reaction (67) follow closely the correlations encountered for the similar reaction in protic solvents (Jencks and Carriuolo, 1960). This observation, plus the fact that in the case of esters SN2 reactions become competitive with attack at the carbonyl, has been rationalized by several authors (Asubiojo and Brauman, 1979 Comisarow, 1977 Takashima and Riveros, 1978) on the basis of the poor solvation expected for the Sn2 transition state due to charge delocalization. Thus, SN2 reactions are expected to display much larger differences in the gas phase than in solution, when compared with nucleophilic displacement at carbonyl centres. This is reflected in a larger sensitivity of the activation parameters. [Pg.226]

Base-catalysed cyclization of proximate diacetyl aromatics [e.g. o-diaccty I benzene (36)] gives the corresponding enone (37). Relative rates, activation parameters, and isotope effects are reported for (36), and also for 1,8-diacetylnaphthalene, 4,5-diacetylphenanthrene, and 2,2/-diacetylbiphenyl, in aqueous DMSO.61 Reaction proceeds via enolate formation (rate determining for the latter three substrates), followed by intramolecular nucleophilic attack [rate determining for (36)], and finally dehydration. [Pg.11]

Benzocyclobutene-l,2-dione (74) undergoes base-catalysed ring fission between the carbonyls to give 2-formy I benzoate (75). Rate constants, activation parameters, isotope effects, and substituent effects have been measured in water.107 Rapid reversible addition of hydroxide to one carbonyl is followed by intramolecular nucleophilic attack on die otiier, giving a resonance-stabilized carbanionic intermediate (76a)-o-(76b). [Pg.20]

Two mechanisms (i.e. direct hydrolysis and alternatively a path via an unstable acyl phosphate intermediate) are involved in the hydrolysis in phosphate buffer of N-arylsulfonyl / -lactams such as (130).107 The acyl phosphate intermediate can be trapped with hydrazine. The alkaline hydrolysis of some torsionally distorted lactams, i.e. the bridged benz[rfe]isoquinolin-l-ones (131), in 70% (v/v) DMSO-water has been compared under the same conditions with the hydrolysis of AvA-dimethyl-1 -naphthamide (132). The relative rates of reaction and activation parameters indicate the effect of torsional distortion.108 The reaction of the tricyclic azetidinones (133) with trifluoroacetic acid gives the bicyclic thioesters (135). The mechanism may involve acid-catalysed elimination of methanethiol to give an azetinone intermediate (134) which, after nucleophilic attack of the thiol, is converted into (135).109... [Pg.56]

Studies of relative rates, activation parameters, kinetic isotope, and solvent isotope effects, and correlation of rates with an acidity function, have elucidated the mechanisms of cyclization of diacetyl aromatics (23-26) promoted by tetramethyl-ammonium hydroxide in DMSO.32 Rate-determining base-catalysed enolate anion formation from (24-26) is followed by relatively rigid intramolecular nucleophilic attack and dehydration whereas the cyclization step is rate determining for (23). [Pg.333]

The relative reactivity, solvent isotope effect (k /k -)) and activation parameters for the acid-catalysed hydration of allylic alcohols CH2=CR—CH2OH (R = H, Me) have been found to be similar to those for other alkenes. Whereas the results can be interpreted in terms of the conventional Ad-E2 mechanism, computed values for the life-time of possible carbocation intermediates suggest another feasible mechanism for CH2=CHCH20H, according to which the nucleophilic attack by the solvent is concerted with protonation55 56. [Pg.1141]

A Cr(VI)-catalyst complex has been proposed as the reactive oxidizing species in the oxidation of frans-stibene with chromic acid, catalysed separately by 1,10-phenanthroline (PHEN), oxalic acid, and picolinic acid (PA). The oxidation process is believed to involve a nucleophilic attack of the olefinic bond on the Cr(VI)-catalyst complex to generate a ternary complex.31 PA- and PHEN-catalysed chromic acid oxidation of primary alcohols also is proposed to proceed through a similar ternary complex. Methanol- reacted nearly six times slower than methanol, supporting a hydride transfer mechanism in this oxidation.32 Kinetics of chromic acid oxidation of dimethyl and diethyl malonates, in the presence and absence of oxalic acid, have been obtained and the activation parameters have been calculated.33 Reactivity in the chromic acid oxidation of three alicyclic ketoximes has been rationalized on the basis of I-strain. Kinetic and activation parameters have been determined and a mechanism... [Pg.94]

Robinson, 1969a). It is probable that the hydrophobic nature of the phenyl groups of p-nitrophenyl diphenyl phosphate results in deep penetration of the neutral ester in the Stern layer, thus shielding the phosphoryl group from nucleophilic attack. Unlike other reactions between nucleophiles and neutral substrates catalyzed by cationic micelles (Bunton and Robinson, 1968, 1969a) and the hydrolysis of dinitrophenyl phosphate dianions in the presence of cationic micelles (Bunton et al., 1968), the catalysis of the hydrolysis of -nitrophenyl diphenyl phosphate by CTAB arises from an increase in the activation entropy rather than from a decrease in the enthalpy of activation. The Arrhenius parameters for the micelle-catalyzed and inhibited reactions are most probably manifestations of the extensive solubilization of this substrate. However, these parameters can be composites of those for the micellar and non-micellar reactions and the eifects of temperature on the micelles themselves are not known. Interpretation of the factors which affect these parameters must therefore be carried out with caution. In addition, the inhibition of the micelle-catalyzed reactions by added electrolytes has been observed (Bunton and Robinson, 1969a Bunton et al., 1969, 1970) and, as in the cases of other anion-molecule reactions and the heterolysis of dinitrophenyl phosphate dianions, can be reasonably attributed to the exclusion of the nucleophile by the anion of the added salt. [Pg.335]

In a manner similar to that of olefins, bicyclobutanes substituted by electron-withdrawing groups at the bridgehead position can undergo facile nucleophilic attacks. Studies of alkoxide-catalyzed additions of alcohols to bicyclobutanecarbonitrile (35, R = H) (equation 73) using crotononitrile as a reference olefin (equation 74), showed that the two substrates resemble one another very much in both their reactivity and activation parameters. ... [Pg.1155]

The activation parameters for the coordination of H2O2 to MTO indicate a mechanism involving nucleophilic attack (see also [8]). [Pg.1306]


See other pages where Nucleophilic attack activation parameters is mentioned: [Pg.2571]    [Pg.2570]    [Pg.316]    [Pg.632]    [Pg.83]    [Pg.173]    [Pg.239]    [Pg.180]    [Pg.85]    [Pg.96]    [Pg.100]    [Pg.431]    [Pg.14]    [Pg.281]    [Pg.334]    [Pg.337]    [Pg.41]    [Pg.92]    [Pg.355]    [Pg.49]    [Pg.289]    [Pg.184]    [Pg.14]    [Pg.50]    [Pg.14]    [Pg.312]    [Pg.184]    [Pg.478]    [Pg.56]    [Pg.561]   
See also in sourсe #XX -- [ Pg.223 ]




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