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Alkyl group directing effect

The carbocations that are formed to generate these two products are shown on the left. You will recall that alkyl groups can exert a positive inductive effect (see p. 59), i.e. they can push electrons towards the positively charged carbon atom in the carbocation and so stabilise it. Therefore carbocation A will be more stable than carbocation B because it has two alkyl groups directly attached to the positively charged carbon atom, whereas there is only one alkyl group in carbocation B. [Pg.65]

In this work, we have investigated the effect of attaching one, two or four lipophilic, linear alkyl groups directly to the macrocyclic ring of 18-crown-6 in ionophores 3-7 (Figure 2). The objective was to maintain the flexibility of the macrocyclic polyether ring while enhancing the lipophilicity of the crown ether compound. In addition to these lipophilic 18-crown-6 derivatives, the lipophilic 15-crown-5 compound 8 was also studied. [Pg.159]

Thus, the values calculated for effective polarizability at the nitrogen atom for a series of 49 amines carrying only alkyl groups was correlated directly with their proton affinities, a reaction that introduces a positive charge on the nitrogen atom by protonation (Figure 7-7) [40. ... [Pg.334]

Experimental measurements of dipole moments give size but not direction We normally deduce the overall direction by examining the directions of individual bond dipoles With alkenes the basic question concerns the alkyl groups attached to C=C Does an alkyl group donate electrons to or withdraw electrons from a double bond d This question can be approached by comparing the effect of an alkyl group methyl for exam pie with other substituents... [Pg.196]

Acylation. Acylation is the most rehable means of introducing a 3-substituent on the indole ring. Because 3-acyl substituents can be easily reduced to 3-aLkyl groups, a two-step acylation—reduction sequence is often an attractive alternative to direct 3-aLkylation. Several kinds of conditions have been employed for acylation. Very reactive acyl haUdes, such as oxalyl chloride, can effect substitution directiy without any catalyst. Normal acid chlorides are usually allowed to react with the magnesium (15) or 2inc (16) salts. The Vilsmeier-Haack conditions involving an amide and phosphoms oxychloride, in which a chloroiminium ion is the active electrophile, frequentiy give excellent yields of 3-acylindoles. [Pg.85]

A mechanism has been proposed to rationalize the results shown in Figure 23. The relative proportion of the A -pyrazolines obtained by the reduction of pyrazolium salts depends on steric and electronic effects. When all the substituents are alkyl groups, the hydride ion attacks the less hindered carbon atom for example when = Bu only C-5 is attacked. The smaller deuterohydride ion is less sensitive to steric effects and consequently the reaction is less selective (73BSF288). Phenyl substituents, both on the nitrogen atom and on the carbon atoms, direct the hydride attack selectively to one carbon atom and the isolated A -pyrazoline has the C—C double bond conjugated with the phenyl (328 R or R = Ph). Open-chain compounds are always formed during the reduction of pyrazolium salts, becoming predominant in the reduction of amino substituted pyrazoliums. [Pg.243]

Substitution reactions by the ionization mechanism proceed very slowly on a-halo derivatives of ketones, aldehydes, acids, esters, nitriles, and related compounds. As discussed on p. 284, such substituents destabilize a carbocation intermediate. Substitution by the direct displacement mechanism, however, proceed especially readily in these systems. Table S.IS indicates some representative relative rate accelerations. Steric effects be responsible for part of the observed acceleration, since an sfp- caibon, such as in a carbonyl group, will provide less steric resistance to tiie incoming nucleophile than an alkyl group. The major effect is believed to be electronic. The adjacent n-LUMO of the carbonyl group can interact with the electnai density that is built up at the pentacoordinate carbon. This can be described in resonance terminology as a contribution flom an enolate-like stmeture to tiie transition state. In MO terminology,.the low-lying LUMO has a... [Pg.301]

This shows a direct relationship of nonpolar /i-alkyl groups with the stabilizing effectiveness of the tin compound. The larger the number of nonpolar -alkyl groups attached to tin, the more effective it is in retarding dehydrochlorination. [Pg.331]

Inductive and resonance effects account for the directing effects of substituents as well as for their activating or deactivating effects. Take alkyl groups, for instance, which have an electron-donating inductive effect and are ortho and para directors. The results of toluene nitration are shown in Figure 16.13. [Pg.565]

Substituted indenes provide other examples of substituent directive effects. Over Pd-alumina, the indenols 6a-c show both cis stereoselectivity and a syn directive effect. The directive effect is reinforced by steric effects as the alkyl group becomes larger.7... [Pg.373]

The syntheses in Schemes 13.45 and 13.46 illustrate the use of oxazolidinone chiral auxiliaries in enantioselective synthesis. Step A in Scheme 13.45 established the configuration at the carbon that becomes C(4) in the product. This is an enolate alkylation in which the steric effect of the oxazolidinone chiral auxiliary directs the approach of the alkylating group. Step C also used the oxazolidinone structure. In this case, the enol borinate is formed and condensed with an aldehyde intermediate. This stereoselective aldol addition established the configuration at C(2) and C(3). The configuration at the final stereocenter at C(6) was established by the hydroboration in Step D. The selectivity for the desired stereoisomer was 85 15. Stereoselectivity in the same sense has been observed for a number of other 2-methylalkenes in which the remainder of the alkene constitutes a relatively bulky group.28 A TS such as 45-A can rationalize this result. [Pg.1205]


See other pages where Alkyl group directing effect is mentioned: [Pg.895]    [Pg.611]    [Pg.629]    [Pg.155]    [Pg.459]    [Pg.459]    [Pg.611]    [Pg.507]    [Pg.689]    [Pg.590]    [Pg.172]    [Pg.336]    [Pg.504]    [Pg.313]    [Pg.512]    [Pg.33]    [Pg.101]    [Pg.290]    [Pg.269]    [Pg.562]    [Pg.336]    [Pg.504]    [Pg.120]    [Pg.287]    [Pg.562]    [Pg.349]    [Pg.685]    [Pg.422]    [Pg.334]    [Pg.106]    [Pg.298]    [Pg.24]    [Pg.22]    [Pg.60]    [Pg.55]    [Pg.164]    [Pg.205]   
See also in sourсe #XX -- [ Pg.565 ]

See also in sourсe #XX -- [ Pg.565 ]

See also in sourсe #XX -- [ Pg.341 ]

See also in sourсe #XX -- [ Pg.585 ]




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Alkyl groups directing electron-donating effects

Direct alkylation

Direct effects

Directing Electron-Donating Effects of Alkyl Groups

Directing effect

Directing groups

Directional effect

Directive effects

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