Quinoline reactivity

All these special cases involve benzologs with an ortho quinonoid structure. But even this pattern is not universal, a deviation being 2-methylindazole (40), which quaternizes 2.2 times more slowly than its parent compound 1-methylpyrazole (37).122 Indeed, except for the molecules just considered and 1,2-benzisothiazole,122 benzo-fusion is rate retarding. Thus, 1,2-benzisoxazole (indoxazene, 39), reacts 3.2 times, and 1-methylindazole (39) 7.1 times, more slowly than their parent compounds.122 Fusing a benzene ring onto an azole where the heteroatoms are situated 1,3 leads to decreases in rate constants by factors of 5.0, 6.3, and 6.8, respectively, when X of 38 is NMe, S, and O.122 These factors are not much smaller than that obtained from a comparison of pyridine and quinoline reactivities.61,78,79... 

Lindlar Catalyst ( Pd/BaS04/ quinoline)- partially poisoned to reduce activity will only reduce the most reactive functional groups. 

These systems nitrate aromatie eompounds by a proeess of electro-philie substitution, the eharacter of whieh is now understood in some detail ( 6.1). It should be noted, however, that some of them ean eause nitration and various other reactions by less well understood processes. Among sueh nitrations that of nitration via nitrosation is especially important when the aromatic substrate is a reactive one ( 4.3). In reaetion with lithium nitrate in aeetie anhydride, or with fuming nitrie aeid, quinoline gives a small yield of 3-nitroquinoline this untypieal orientation (ef. 10.4.2 ) may be a eonsequenee of nitration following nucleophilic addition. ... 

The use of q and tt separately as reactivity indices can lead to misleading results. Thus, whilst within the approximations used, the use of either separately leads to the same conclusions regarding electrophilic substitution into halogenobenzenes ( 9.1.4), the orientation of substitution in quinoline ( 9.4.2) cannot be explained even qualitatively using either alone. By taking the two in combination, it can be shown that as the values of Sa are progressively increased to simulate reaction, the differences in SE explain satisfactorily the observed orientation. ... 

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. ... 

It is pertinent here to consider some of the results obtained by Greenwood and McWeeny using both q and tt,. as criteria of reactivity ( 7.2.2). They have calculated for quinoline the exact charges in the... 

The oxidative dehydration of isobutyric acid [79-31-2] to methacrylic acid is most often carried out over iron—phosphoms or molybdenum—phosphoms based catalysts similar to those used in the oxidation of methacrolein to methacrylic acid. Conversions in excess of 95% and selectivity to methacrylic acid of 75—85% have been attained, resulting in single-pass yields of nearly 80%. The use of cesium-, copper-, and vanadium-doped catalysts are reported to be beneficial (96), as is the use of cesium in conjunction with quinoline (97). Generally the iron—phosphoms catalysts require temperatures in the vicinity of 400°C, in contrast to the molybdenum-based catalysts that exhibit comparable reactivity at 300°C (98). 

Reactions. Quinoline exhibits the reactivity of benzene and pyridine rings, as weU as its own unique reactions. 

Fused benzene rings are treated as substituents. Thus quinoline, for example, is considered as a substituted pyridine, albeit a very special and important one, and treated alongside other substituted pyridines in the discussion of its structure, reactivity and synthesis. Reactions of quinoline at positions 1-4 are considered as reactions at ring atoms, whilst reactions at positions 5-8 are regarded as reactions of the substituent . 

The benz analogue of 2-trifluoromethylimidazole is inert to aqueous alkali, presumably because formation of the intermediate diazafulvene would disrupt the benzene ring However, two quinoline analogues do undergo hydrolysis with subsequent decarboxylation [4J] (equations 42 and 43) The f4,5-h] isomer is less reactive (equation 42) than the [4,5-f] isomer (equation 43)... 

An interesting use of the Camps quinoline synthesis is in the ring contraction of macrocycles. Treatment of 9 member ring 24 with sodium hydroxide in water furnished quinolin-4-ol 25, while 26 furnishes exclusively quinolin-2-ol 27 under the same reaction conditions (no yield was given for either reaction). The reaction does not work with smaller macrocycles. The authors rationalize the difference in reactivity based upon ground state conformation differences, but do not elaborate. 

Petrow described the formation of 3-iminoketones from 3-keto-aldehydes and aniline. Cyclization in the presence of aniline hydrochloride and ZnCh smoothly provides the desired quinoline 26. Bis-imine 24 is the proposed intermediate that undergoes cyclization. The aldimine is more reactive than the ketimine toward cyclization thus, cyclization on the aldimine occurs. When the bis-imine is not formed, partial aniline migration can occur which results in mixtures of cyclized products. 

Analogous to the selectivity observed for the conversion of 48 into 50, pyridyl 51 formed enamine 52 which underwent cyclization to give 4-pyridyl-substituted quinoline 53. Again, imine formation first occurs on the less hindered ketone and subsequent cyclization on the more reactive carbonyl occurred in high yield. ... 

A -acetyl groups attached to the aniline have been shown to withstand the Conrad-Limpach reaction. Phenols and alcohols also survived unless in proximity to a reactive center. Jaroszewski reported the formation of 64 by reaction of aniline 63 with ethyl acetoacetate (5). Cyclization under thermal conditions in paraffin gave a mixture of quinolone 65 and quinoline 66. 

Primary halides are more reactive than secondary compounds quaternary salt formation does not occur with tertiary halides, elimination always occurring to give the hydriodide and an olefln, Also, the larger the alkyl group the slower is the reaction this is shown by the very slow reaction of dodecyl bromide with quinoline, and even butyl iodide is much slower to react than methyl iodide. The longer chain primary halides commonly undergo elimination rather than cause quaternization for example, n-octyl and cetyl iodides give only the hydriodides when heated with 9-aminoacridine. ... 

A COMPAMSON OF THE REACTIVITIES OF ChLOBO-QUINOLINES WITH MeTHOXIDE AND AbYLSUDFIDE... 

The usual order found with halogenonitrobenzenes is F > Cl Br I, the order of Cl and Br being variable, just as in heteroaromatic reactivity. The position of fluorine is of interest the available data indicate that it is usually the same as for nitrobenzene derivatives. Thus, in acid hydrolysis the order F > Cl for 2-halogeno-quinolines can be deduced beyond doubt since the fluoro derivative appears to react in the non-protonated form and the chloro derivative to resist hydrolytic attack even in the protonated form under appropriate conditions (Section II,D, l,d). Furthermore, in the benzo-thiazole ring, fluorine is displaced by the CHgO reagent at a rate 10 times that for chlorine. ... 

The A-oxidation of 3-chloropyridazines increases their reactivity toward methoxide and sulfanilamide anions.The reactivity of 4-chloro- or 4-nitro-quinoline and of chloropyridines toward methoxide ion and piperidine is less than that of the corresponding A-oxides (see Tables II and XI, pp. 270 and 338). The activating effect of the A-oxide moiety in 3-halopyridine A-oxides is greater than that of a nitro group, and in fluoroquinoline A-oxides the activation is transmitted to resonance-activated positions in the adjoining rings. 

Aryloxy, hydroxy arylsulfonyloxy, and phosphoryloxy. The 4-toluenesulfonyloxy and 4-nitrophenyloxy groups approximate the chloro group in replaceability in benzene derivatives. The former appears to be less reactive than chloro toward hydroxide on quinoline and -phenoxy on pyrimidine is relatively unreactive toward sulfanilamide anion or ammonia. On cinnoline, quinazoline, or quinoline, a 4-phenoxy group is less reactive than a chloro group. 

Indirect deactivation by an alkoxy group is apparent in the sluggish reaction of 4-butoxy-2-chloroquinoline with w-butylamine (EtOH, 5 hr, 180°, but not at 80°). The chloro group in 2-chloro-4-ethoxy-quinoline is more reactive than that in the 4-chloro-2-ethoxy isomer toward alkoxides or amines in spite of the usually more effective para indirect deactivation in the former. For kinetic data on quinolines see Tables X and XI, pp. 336 and 338, respectively. 

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