Aldehydes, acidic behavior

In the case of aqueous solutions of organic compounds, the determination of yields was often effected for onlv a single concentration of the solute. On another hand, the yields were frequently indicated by the authors only for some of the formed products. Sometimes, only the function of the formed product (aldehyde, acid,...) was identified. Although these determinations present merely a limited interest, they were given because ihev nevertheless point out the qualitative behavior of the compounds. 

Aldehydes. Acetaldehyde is the only aliphatic aldehyde whose behavior towards hydrazoic acid has been reported it yields acetonitrile. ... 

Another example of the acidic behavior of the amphoteric aldehyde and the basic action of a catalyst in this type of reaction is the formation of benzyl benzoate under anhydrous conditions ... 

Phenolic resins were the first totally synthetic plastics invented. They were commercialized by 1910 [I]. Their history begins before the development of the structural theory of chemistry and even before Kekule had his famous dreams of snakes biting their tails. It commences with Gerhardt s 1853 observations of insoluble resin formation while dehydrating sodium salicylate [2]. These were followed by similar reports on the behavior of salicylic acid derivatives under a variety of reaction conditions by Schroder et al. (1869), Baeyer (1872), Velden (1877), Doebner (1896 and 1898), Speyer (1897) and Baekeland (1909-1912) [3-17]. Many of these early reports appear to involve the formation of phenolic polyesters rather than the phenol-aldehyde resins that we think of today. For... 

Adolph Baeyer is credited with the first recognition of the general nature of the reaction between phenols and aldehydes in 1872 ([2,5-7] [18], Table 5.1). He reported formation of colorless resins when acidic solutions of pyrogallic acid or resorcinol were mixed with oil of bitter almonds, which consists primarily benzaldehyde. Baeyer also saw resin formation with acidic and basic solutions of phenol and acetaldehyde or chloral. Michael and Comey furthered Baeyer s work with additional studies on the behavior of benzaldehyde and phenols [2,19]. They studied a variety of acidic and basic catalysts and noted that reaction vigor followed the acid or base strength of the catalyst. Michael et al. also reported rapid oxidation and darkening of phenolic resins when catalyzed by alkaline materials. 

Fire Hazards - Flash Point (deg. F) 285 OC Flammable Limits in Air (%) 0.8 - 5.0 Fire Extinguishing AgerUs Alcohol foam, dry chemical, or carbon dioxide Fire Extinguishing Agents Not To Be Used Water may be ineffective Special Hazards of Combustion Products Acrid fumes of acids and aldehydes may form in fires Behavior in Fire No data Ignition Temperature No data Electrical... 

The difference in behavior between aldehydes/ketones and carboxylic acic derivatives is a consequence of structure. Carboxylic acid derivatives have ai acyl carbon bonded to a group -Y that can leave as a stable anion. As soon a the tetrahedral intermediate is formed, the leaving group is expelled to general- a new carbonyl compound. Aldehydes and ketones have no such leaving grouj however, and therefore don t undergo substitution. 

Using a delicate reduction method, the aldehyde group can be converted to a sixth hydroxyl group, giving the substance called sorbitol. This compound shows the typical behavior of an alcohol. For example, it forms esters with acids ... 

Photocatalytic oxidation is a novel approach for the selective synthesis of aldehyde and acid from alcohol because the synthesis reaction can take place at mild conditions. These reactions are characterized by the transfer of light-induced charge carriers (i.e., photogenerated electron and hole pairs) to the electron donors and acceptors adsorbed on the semiconductor catalyst surface (1-4). Infrared (IR) spectroscopy is a useful technique for determining the dynamic behavior of adsorbed species and photogenerated electrons (5-7). 

Reduction to Alcohols. The organosilane-mediated reduction of ketones to secondary alcohols has been shown to occur under a wide variety of conditions. Only those reactions that are of high yield and of a more practical nature are mentioned here. As with aldehydes, ketones do not normally react spontaneously with organosilicon hydrides to form alcohols. The exceptional behavior of some organocobalt cluster complex carbonyl compounds was noted previously. Introduction of acids or other electrophilic species that are capable of coordination with the carbonyl oxygen enables reduction to occur by transfer of silyl hydride to the polarized carbonyl carbon (Eq. 2). This permits facile, chemoselective reduction of many ketones to alcohols. 

The sex pheromones of moths generally are mixtures of two or more chemical components, typically aldehydes, acetates, alcohols, or hydrocarbons, produced in specialized glands by biosynthesis and modification of fatty acids (34). Often, a species-specific blend of components is the message, and males of many moth species, including M. sexta, give their characteristic, qualitatively and quantitatively optimal behavioral responses only when stimulated by the correct blend of sex-pheromone components and not by individual components or partial blends lacking key components (43, 44). 

Circulation flow system, measurement of reaction rate, 28 175-178 Clausius-Clapeyron equation, 38 171 Clay see also specific types color tests, 27 101 compensation behavior, 26 304-307 minerals, ship-in-bottle synthesis, metal clusters, 38 368-379 organic syntheses on, 38 264-279 active sites on montmorillonite for aldol reaction, 38 268-269 aldol condensation of enolsilanes with aldehydes and acetals, 38 265-273 Al-Mont acid strength, 38 270-271, 273 comparison of catalysis between Al-Mont and trifluorometfaanesulfonic acid, 38 269-270... 

Decomposition of the copper complex with HjS in acid leads to allothreonine and (in about 2-fold excess) threonine. Following the pioneering work of Akabori et this reaction has been extended to a variety of metals and aldehydes and to complexes such as A- and A-Co(en)2gly with intriguing stereoselectivity behavior (optically-active allothreonine and threonine products). ... 

A stereochemical behavior similar to that of the 1-bromo-l-lithio aUcene 164 with regard to chiral aldehydes is shown by the hthiated methoxyallene 183. When added to iV,iV-dibenzylated a-aminoaldehydes 188, it reacts with non-chelate control so that awh -carbinols 189 are obtained predominantly. Diastereomeric ratios of 189 190 range from 80 20 to 95 5. As outlined above, the hydroxyalkylated allenes 189/190 can be converted into furanones 191/192 upon treatment with potassium f-butoxide and subsequent acid hydrolysis" . When, on the other hand, the adducts of 183 to the aldehydes 193 are submitted to an ozonolysis, A-protected a-hydroxy-/3-amino esters 194/195 result (Scheme 25)"" . 

The behavior of 2-substituted- or 2-unsubstituted-5(4//)-oxazolones is completely different. Reaction of electrophiles with 2-substimted-5(47/)-oxazolones usually occurs at C-4, whereas reaction of electrophiles with 2-unsubstituted-5(47/)-oxazolones affords the corresponding 5(2//)-oxazolones. The best example of the behavior of 2-unsubstituted-5(47/)-oxazolones involves 4-isopropyl-5(47/)-oxazolone 143, the anion of which can be considered as a formyl anion equiva-lent. ° ° Thus, reaction of 143 with a catalytic amount of triethylamine gives 144 that reacts with a,p-unsaturated carbonyl compounds to afford Michael adducts or with aldehydes to produce the corresponding aldol adducts. Mild acid hydrolysis of 145 yields the corresponding aldehydes (Scheme 7.42). 

Direct electrophilic substitution of benz- and dibenz-azepines remains relatively unexplored. Most substituted benzazepines have been prepared from benzene precursors bearing the desired substituents (74AHC(17)45). The bulk of the reported electrophilic substitutions have been carried out on 5//-dibenz[6,/]azepine (74CRV101), MO calculations on which predict that substitution should occur at the 2- and 4-positions, i.e. para and ortho to the azepine ring nitrogen. These predictions are borne out by Friedel-Crafts alkylation and acylation studies, although it is apparent that a second alkyl group enters at the 8- rather than at the 4-position. Formylation under Vilsmeier conditions yields the 2-aldehyde. As noted earlier (Section 5.16.3.4), however, the 10,11-dihydro system exhibits different behavior and acylates at the benzylic 10,11-positions. Nitration with mixed acids of the... 

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