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Aromatic compound reaction summary

Most dihydro-1,2,4-triazines have been prepared by addition of nucleophiles to 1,2,4-triazines, but in general the dihydro-1,2,4-triazines were not isolated but oxidized back to the fully aromatic systems. Section 6.11.5.7.(iii) covers these reactions, from the aspect of the reactivity of the fully aromatic compounds. A summary of the main features, and some additional information is presented in this Section. [Pg.538]

In the above examples, the nucleophilic role of the metal complex only comes after the formation of a suitable complex as a consequence of the electron-withdrawing effect of the metal. Perhaps the most impressive series of examples of nucleophilic behaviour of complexes is demonstrated by the p-diketone metal complexes. Such complexes undergo many reactions typical of the electrophilic substitution reactions of aromatic compounds. As a result of the lability of these complexes towards acids, care is required when selecting reaction conditions. Despite this restriction, a wide variety of reactions has been shown to occur with numerous p-diketone complexes, especially of chromium(III), cobalt(III) and rhodium(III), but also in certain cases with complexes of beryllium(II), copper(II), iron(III), aluminum(III) and europium(III). Most work has been carried out by Collman and his coworkers and the results have been reviewed.4-29 A brief summary of results is relevant here and the essential reaction is shown in equation (13). It has been clearly demonstrated that reaction does not involve any dissociation, by bromination of the chromium(III) complex in the presence of radioactive acetylacetone. Furthermore, reactions of optically active... [Pg.420]

In summary, catalytic C-H transformations in small unfunctionalized alkanes is a technically very important family of reactions and processes leading to small olefins or to aromatic compounds. The prototypical catalysts are chromia on alumina or vanadium oxides on basic oxide supports and platinum on alumina. Reaction conditions are harsh with a typical minimum temperature of 673 K at atmospheric pressure and often the presence of excess steam. A consistent view of the reaction pathway in the literature is the assumption that the first C-H abstraction should be the most difficult reaction step. It is noted that other than intuitive plausibility there is little direct evidence in heterogeneous reactions that this assumption is correct. From the fact that many of these reactions are highly selective toward aromatic compounds or olefins it must be concluded that later events in the sequence of elementary steps are possibly more likely candidates for the rate-determining step that controls the overall selectivity. A detailed description of the individual reactions of C2-C4 alkanes can be found in a comprehensive review [59]. [Pg.598]

A SUMMARY OF REACTIONS AVAILABLE FOR USE IN THE SYNTHESIS OF AROMATIC COMPOUNDS. [Pg.713]

Summary Reactions of Aromatic Compounds 805 EssentialTerms 808 Study Problems 810... [Pg.17]

In summary, the kinetic observations for aromatic nitration provide a consistent pattern of results. Conventional behavior Is observed in the aqueous acid solvents for the compounds which are less reactive than the xylenes. However, the aromatic compounds which are approximately 50-fold more reactive than benzene exhibit a limiting reaction rate In these solvents. The rate limit can be identified with the diffusion controlled formation of the encounter complex. [Pg.59]

The formation of a complex prior to reaction is well supported in the case of bromination. Molecular bromine forms charge transfer complexes with benzene even in the absence of Lewis acid catalysts. The complexes can be detected spectroscopically and can even be crystallized for structure determination. Complexes of Br with the aromatic compound may also be formed. For a summary of experimental data in this area, see the discussion in reference 178. [Pg.520]

The summary of experimental results of the alkylation of various aromatic compounds has been divided into tables on the basis of the aromatic compound alkylated. These tables summarize the reagents and catalysts used for the various alkylations and, when available, such details as moles of reactants, solvent, temperature, time of reaction, products, and yields. [Pg.19]

Section 12 1 On reaction with electrophilic reagents compounds that contain a ben zene ring undergo electrophilic aromatic substitution Table 12 1 m Section 12 1 and Table 12 3 m this summary give examples... [Pg.508]

Enzymatic transformations of alkaloids by peroxidases most probably occur by single-step oxidations catalyzed by the HRP-I and HRP-II forms of the enzyme. The catalysis of one-electron oxidations of compounds containing aromatic hydrocarbon, hydrazine, phenol, hydroxamic acid, and amine functional groups has been recently reviewed (45, 58, 82). A brief summary of those HRP reactions that involve functional groups most commonly occurring in alkaloids is presented below. [Pg.347]

This initial attack of the ozone molecule leads first to the formation of ortho- and para-hydroxylated by-products. These hydroxylated compounds are highly susceptible to further ozonation. The compounds lead to the formation of quinoid and, due to the opening of the aromatic cycle, to the formation of aliphatic products with carbonyl and carboxyl functions. The nucleophilic reaction is found locally on molecular sites showing an electronic deficit and, more frequently, on carbons carrying electron acceptor groups. In summary, the molecular ozone reactions are extremely selective and limited to unsaturated aromatic and aliphatic compounds as well as to specific functional groups. [Pg.244]

The routes give, using well-known condensation and radical reactions, bakelites (I), polyazophenylenes (II), polyimides (III), polyurethanes (IV), nitro compounds and polyamides (V), aromatic polyethers and polyesters (VI), polychalcones (VII), polyphenylene sulfides (IX), ammonia lignin (X), carbon fibers (XI), silicones (XII), and phosphorus esters (XIII). In addition, radiation and chemical grafting can be used to obtain polymers of theoretical interest and practical use. Although the literature on the above subject is very large, there are comprehensive summaries available (1,28,69). [Pg.202]

Free amino acids are further catabolized into several volatile flavor compounds. However, the pathways involved are not fully known. A detailed summary of the various studies on the role of the catabolism of amino acids in cheese flavor development was published by Curtin and McSweeney (2004). Two major pathways have been suggested (1) aminotransferase or lyase activity and (2) deamination or decarboxylation. Aminotransferase activity results in the formation of a-ketoacids and glutamic acid. The a-ketoacids are further degraded to flavor compounds such as hydroxy acids, aldehydes, and carboxylic acids. a-Ketoacids from methionine, branched-chain amino acids (leucine, isoleucine, and valine), or aromatic amino acids (phenylalanine, tyrosine, and tryptophan) serve as the precursors to volatile flavor compounds (Yvon and Rijnen, 2001). Volatile sulfur compounds are primarily formed from methionine. Methanethiol, which at low concentrations, contributes to the characteristic flavor of Cheddar cheese, is formed from the catabolism of methionine (Curtin and McSweeney, 2004 Weimer et al., 1999). Furthermore, bacterial lyases also metabolize methionine to a-ketobutyrate, methanethiol, and ammonia (Tanaka et al., 1985). On catabolism by aminotransferase, aromatic amino acids yield volatile flavor compounds such as benzalde-hyde, phenylacetate, phenylethanol, phenyllactate, etc. Deamination reactions also result in a-ketoacids and ammonia, which add to the flavor of... [Pg.194]

Reviews of the biodegradation and biotransformation of nitroaroamatic compounds have been given (Spain 1995a,b Crawford 1995) to which reference should be made for details, so that only a very brief summary is justified here. Three principal reactions are found among aerobic bacteria (1) oxidative elimination of nitrite, (2) partial or complete reduction of the nitro group, and (3) reduction of the aromatic ring (Chapter 6, Section 6.8.2). [Pg.829]

Aliphatic nitro compounds cannot as a rule be prepared in the same way as the aromatic nitro compounds. The more rapid oxidation of aliphatic hydrocarbons by nitric acid is the main interfering factor, so that conditions must be chosen which minimize oxidation and promote nitration. The oxidation reactions are of such complexity in these cases that no attempt will be made to formulate them. Only a summary of the conditions favoring nitration will be given. The use of a solvent such as ether for carrying out the reaction is often successful. Also dilute nitric acid has been used, and alkyl (generally ethyl) nitrate. In the Friedel-Crafts reaction with ethyl nitrate, aluminium chloride is used as catalyst. In aliphatic nitrations with ethyl nitrate, alkalis such as metal alkoxides (NaOC Hs) are found to be best. The use of alkalis brings out the similarity of this reaction to aldol condensations which are also favored by alkalis. An example of aliphatic nitration, in comparison with an aromatic one may be given ... [Pg.115]

See other pages where Aromatic compound reaction summary is mentioned: [Pg.81]    [Pg.2297]    [Pg.284]    [Pg.69]    [Pg.28]    [Pg.103]    [Pg.224]    [Pg.794]    [Pg.107]    [Pg.1375]    [Pg.186]    [Pg.713]    [Pg.150]    [Pg.540]    [Pg.314]    [Pg.317]    [Pg.814]    [Pg.1532]    [Pg.317]    [Pg.1499]    [Pg.351]    [Pg.483]    [Pg.354]    [Pg.563]    [Pg.174]   
See also in sourсe #XX -- [ Pg.356 ]



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