Meta substitution, definition

Because the rate of substitution varies with position, in a benzene derivative it is more informative and frequently more useful to talk about partial rate factors than about relative rates. A partial rate factor is defined as the rate at one particular position in the benzene derivative relative to the rate of substitution at one position in benzene. Let us, for example, calculate the para and meta partial rate factors (pf and mf, respectively) for bromination of toluene with bromine in aqueous acetic acid. Toluene brominates 605 times faster than benzene under these conditions. The product is 66.8 percent p-, 0.3 percent m-, and 32.9 percent o-bromotoluene. Attack at the para position of toluene occurs 0.668 x 605 times as fast as attack at all six positions of benzene but (0.668 x 605 x 6 = 2420) times as fast as at one position of benzene. Therefore pfCH for bromination of toluene under these conditions is 2420. There are only three times as many total carbons in benzene as meta carbons in toluene. Therefore mfca3 = 0.003 x 605 x 3 = 5.5. The definitions of the partial rate factors for monosubstituted benzenes (—R) are given in Equations 7.78-7.80. 

The intermediate 1,5-dicarbonyl compounds of type 24 (Scheme 1) can be constructed not only on the basis of meta-alkoxy-substituted benzyl ketones (C4 + Ci synthesis, Section II,C), but also under definite conditions starting from aryl ketones (C2 + C3 synthesis). Thus, in a molecule of acylveratrole derivatives of type 79, the excess of 7r-electron density due to the presence of two ortho-methoxy groups allows such compounds to be involved in electrophilic substitutions with benzoin (73URP2 74KGS1575). 

Derivatives of Biphenyl. By coupling diazo compounds and N-nitrosoacetyl derivatives obtained from substituted anilines with benzene, a large variety of biphenyl derivatives can be prepared in which only one of the rings is substituted. In this manner, the isomeric monosubstituted biphenyls, RCel CeHs, have been prepared in which R = Br, Cl, CH3, OCH3, NO2, CN, etc. The meta derivatives, such as 3-brQmobiphenyl (I), 3-nitrobiphenyl (II), and 3-cyanobiphenyl (III), are of particular interest because they cannot be prepared readily from biphenyl. The usefulness of the methods for the preparation of compounds of definite... 

Ounnar and co-workers [31,32] widely apply in their QSRR studies the approach called correspondence factor analysis (CFA). CFA is mathematically related to PCA, differing in the preprocessing and scaling of the data. Those authors often succeeded in assigning definite physical sense to abstract factors, e.g., they identified the Hammett constants of substituents in meta and para positions of 72 substituted /V-benzylideneanilines (NBA) in determining the first factorial axis resulting from the CFA analysis of retention data of NBA in diverse normal-phase HPLC systems. 

Di-substitution Products.—Usually however the di-substitution products are designated by numbers as first indicated. The names ortho, meta and para are also sometimes used exactly as in the benzene products together with other similar names applying to definite pairs of positions. By examining the formula we shall find that ten isomeric di-substitution products of naphthalene are possible in case the two substituents are the same. These ten with their numerical designations and names are as follows ... 

Provided there is no resonance transmission in the effect of substituents on the dissociation of acetic acids (as would be expected) then the linear equation indicates that the transmission of the effect of the meta substituent does not involve resonance either. The correlation shows that provides a useful secondary definition of Oi. This relationship is a Class II free energy correlation between the dissociation of substituted acetic acids and weZa-substituted benzoic acids. 

The D values in Table 4 display some interesting and remarkable trends in the spin-delocalizing ability of the heteroaryl substituents. The three regio-isomeric pyridyl-substituted triplet diradicals 12g ( — 0.01), 12i ( — 0.05), and 12k (—0.06) delocalize spin worse than the phenyl reference system in the order para > ortho > meta phenyl. Especially in the ortho and para isomers delocalization is definitely less effective than for phenyl. Thus, the pyridyl derivatives act as spin donors by enhancing the spin density at the radical site, although the effects are relatively small. The small effects are mainly due to destabilizing aminyl-type radical structures with unfavorable spin accumulation at the nitrogen atom (Fig. 20) [61]. 

In general, the Perkin reaction is limited to aromatic aldehydes. The activity of substituted benzaldehydes in the Perkin reaction is similar to the trends observed in other reactions involving the carbonyl group. A halogen (28) or nitro (34) group in any position increases the rate of reaction and the yield a methyl group (26) in any position decreases the rate and yield, and this effect falls off in the order ortho > meta > para A methoxy group in the ortho position (30) has a small favorable influence, but in the para position (32) it has a definite unfavorable effect on the rate and yield. 

Because a is defined by a similar model the action of meta or ortho substituents is tantamount to a single interaction pathway. When the transmission path in the ionisation of benzoic acids differs from that in the unknown reaction special treatment is required [42]. In the case of substituted aspirins the carboxyl group is involved in catalysis. Thus two pathways exist for substituent transmission not comparable with the simple Hammett definition of a an alternative approach is to look at the substituents and realise that a problem exists in assigning a values (Eqn. 56). 

In these equations, k or k2 refer to the rate or equilibrium constant for the unsubstituted molecule, p characterizes the sensitivity of the reaction to electronic substituent effects, and a is the relative electronic effect of the substituent. A substituent at the meta position has a different a value than that of the same substituent at the para position. By definition, p = 1.0 for the pi a of substituted benzoic acids and a is the substituent effect on this reaction. As an example, Figure 3.1 shows the relationship between Hammett a and the log of the acid dissociation constant (log Kf of metu-substituted phenols. The correlation coefficient of this relationship is 0.97. The data is presented in Table 3.1. 

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