Substitutions prediction

While it was known that lime or lemon juice would prevent scurvy the active ingredient remained elusive. Experiments were conducted using dilute hydrochloric acid as a substitute. Predictably, they did not work. 

Electron density calculations suggest that electrophilic attack in pyridine (42) is favored at C-3, whereas nucleophilic attack occurs preferentially at C-2 and to a lesser extent at C-4. Cytochrome P-450 mediated ring hydroxylation of pyridine would, therefore, be expected to occur predominantly at C-3, the most electron-rich carbon atom. Although 3-hydroxypyridine is an in vivo metabolite in several species, the major C-oxidation product detected in the urine of most species examined was 4-pyridone (82MI10903). The enzyme system catalyzing the formation of this latter metabolite may involve the molybdenum hydroxylases and not cytochrome P-450 (see next paragraph). In the related heterocycle quinoline (43), positions of high electron density are at C-3, C-6 and C-8, while in isoquinoline (44) they are at C-5, C-7 and C-8. Nucleophilic substitution predictably occurs... 

This same factor accounts for the 3-substitution predicted for imida-zo[l,2-fl]pyridine, imidazopyrimidines, and imidazol[l,2-a]pyrazine by both frontier electron densities (Scheme 8.10) and ir-electron densities (not shown) (74JHC1013 82AJC1761). The former indicate the 5- or 7-positions to be the next most reactive, whereas the latter indicate it to be the 2-position which is more probably correct (cf. indolizine) in general, frontier electron densities are poorer indices of aromatic reactivity. 

Understand the mechanisms of electrophilic and nucleophilic aromatic substitutions. Predict the products of these reactions and use them in syntheses. 

Your chance to rehearse the methods of control in allylic substitution. Prediction is more diffic-r.c than explanation. 

PROBLEM 15.90 Select the reaction Nucleophilic aromatic substitution. Predict the H NMR spectra of the starting material (l-chloro-2,4-dinitrobenzene) and the product (AAmethyl-2,4-dinitroaniline). How would the IR data differ for the starting material and the product ... 

More precisely, the rate of ozone formation depends closely on the chemical nature of the hydrocarbons present in the atmosphere. A reactivity scale has been proposed by Lowi and Carter (1990) and is largely utilized today in ozone prediction models. Thus the values indicated in Table 5.26 express the potential ozone formation as O3 formed per gram of organic material initially present. The most reactive compounds are light olefins, cycloparaffins, substituted aromatic hydrocarbons notably the xylenes, formaldehyde and acetaldehyde. Inversely, normal or substituted paraffins. 

A brief account of aromatic substitution may be usefully given here as it will assist the student in predicting the orientation of disubstituted benzene derivatives produced in the different substitution reactions. For the nitration of nitrobenzene the substance must be heated with a mixture of fuming nitric acid and concentrated sulphuric acid the product is largely ni-dinitrobenzene (about 90 per cent.), accompanied by a little o-dinitrobenzene (about 5 per cent.) which is eliminated in the recrystallisation process. On the other hand phenol can be easily nitrated with dilute nitric acid to yield a mixture of ortho and para nitrophenols. It may be said, therefore, that orientation is meta with the... 

Dewar and his co-workers, as mentioned above, investigated the reactivities of a number of polycyclic aromatic compounds because such compounds could provide data especially suitable for comparison with theoretical predictions ( 7.2.3). This work was extended to include some compounds related to biphenyl. The results were obtained by successively compounding pairs of results from competitive nitrations to obtain a scale of reactivities relative to that of benzene. Because the compounds studied were very reactive, the concentrations of nitric acid used were relatively small, being o-i8 mol 1 in the comparison of benzene with naphthalene, 5 x io mol 1 when naphthalene and anthanthrene were compared, and 3 x io mol 1 in the experiments with diphenylamine and carbazole. The observed partial rate factors are collected in table 5.3. Use of the competitive method in these experiments makes them of little value as sources of information about the mechanisms of the substitutions which occurred this shortcoming is important because in the experiments fuming nitric acid was used, rather than nitric acid free of nitrous acid, and with the most reactive compounds this leads to a... 

The isolated molecule treatment of reactivity, which, in both the electronic theory and in m.o. theory, attempts to predict the site of electrophilic substitution from a consideration of the electron densities... 

M.o. theory has had limited success in dealing with electrophilic substitution in the azoles. The performances of 7r-electron densities as indices of reactivity depends very markedly on the assumptions made in calculating them. - Localisation energies have been calculated for pyrazole and pyrazolium, and also an attempt has been made to take into account the electrostatic energy involved in bringing the electrophile up to the point of attack the model predicts correctly the orientation of nitration in pyrazolium. ... 

Numerous m.o.-theoretical calculations have been made on quinoline and quinolinium. Comparisons of the experimental results with the theoretical predictions reveals that, as expected (see 7.2), localisation energies give the best correlation. jr-Electron densities are a poor criterion of reactivity in electrophilic substitution the most reactive sites for both the quinolinium ion and the neutral molecule are predicted to be the 3-, 6- and 8-positions. ... 

Calculations for electrophilic substitution in the quinolinium ion can be compared with experiment, and for a range of values of h the predicted order of positional reactivities, s 8>6>3>7, agrees moderately well in a qualitative sense with the observed order of s 8>6>7>3 (table 10.3). Further evaluation of the method must await the results of more extensive calculations for a range of aromatic systems. 

Substitution can take place by the S l or the 8 2 mechanism elimination by El or E2 How can we predict whether substitution or elimination will be the principal reac tion observed with a particular combination of reactants The two most important fac tors are the structure of the alkyl halide and the basicity of the anion It is useful to approach the question from the premise that the characteristic reaction of alkyl halides with Lewis bases is elimination and that substitution predominates only under certain special circumstances In a typical reaction a typical secondary alkyl halide such as iso propyl bromide reacts with a typical Lewis base such as sodium ethoxide mainly by elimination... 

Each of the following nucleophilic substitution reactions has been reported in the chemical literature Many of them involve reactants that are somewhat more complex than those we have dealt with to this point Nevertheless you should be able to predict the product by analogy to what you know about nucleophilic substitution in simple systems... 

When a benzene ring bears two or more substituents both its reactivity and the site of further substitution can usually be predicted from the cumulative effects of its substituents In the simplest cases all the available sites are equivalent and substitution at any one of them gives the same product... 

The least sterically hindered p hydrogen is removed by the base m Hofmann elim matron reactions Methyl groups are deprotonated m preference to methylene groups and methylene groups are deprotonated m preference to methmes The regioselectivity of Hofmann elimination is opposite to that predicted by the Zaitsev rule (Section 5 10) Elimination reactions of alkyltrimethylammonmm hydroxides are said to obey the Hofmann rule, they yield the less substituted alkene... 

Predict the products formed when each of the following isotopically substituted denvatives of chlorobenzene is treated with sodium amide in liquid ammonia Estimate as quantitatively as possible the composition of the product mixture The astensk ( ) in part (a) designates C and D in part (b) is... 

The sign of AG can be used to predict the direction in which a reaction moves to reach its equilibrium position. A reaction is always thermodynamically favored when enthalpy decreases and entropy increases. Substituting the inequalities AH < 0 and AS > 0 into equation 6.2 shows that AG is negative when a reaction is thermodynamically favored. When AG is positive, the reaction is unfavorable as written (although the reverse reaction is favorable). Systems at equilibrium have a AG of zero. 

If this result is substituted into the previous expressions containing f, the effect is to replace f with (20) " and to multiply those t s which accompany f by t This rather complex array of possibilities is summarized in Table 4.3. Table 4.3 lists the predicted values for the Avrami exponent for the following cases ... 

Historically, the discovery of one effective herbicide has led quickly to the preparation and screening of a family of imitative chemicals (3). Herbicide developers have traditionally used combinations of experience, art-based approaches, and intuitive appHcations of classical stmcture—activity relationships to imitate, increase, or make more selective the activity of the parent compound. This trial-and-error process depends on the costs and availabiUties of appropriate starting materials, ease of synthesis of usually inactive intermediates, and alterations of parent compound chemical properties by stepwise addition of substituents that have been effective in the development of other pesticides, eg, halogens or substituted amino groups. The reason a particular imitative compound works is seldom understood, and other pesticidal appHcations are not readily predictable. Novices in this traditional, quite random, process requite several years of training and experience in order to function productively. 

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