Carboxylic acids ozonolysis

The oxidation of alkenes and cycloalkenes and their halogen derivatives with at least one hydrogen or halogen atom at the double bond leads to carboxylic acids. Ozonolysis usually requires the oxidative decomposition of the ozonide. The oxygen content of the ozonide is not sufficient for the formation of two molecules of acids or one dicarboxylic acid. The nonoxidative decomposition of cyclohexene ozonide gives an aldehyde-acid or its derivatives [1108]. It comes, therefore, as a surprise that carboxylic acids are claimed as products of the decomposition of ozonides by hydrogenation over the Lindlar catalyst [55] (equation 108). 

The same reagents that oxidize alkenes also oxidize alkynes. Alkynes are oxidized to diketones by a basic solution of KMn04 at room temperature and are cleaved by ozonolysis to carboxylic acids. Ozonolysis requires neither oxidative nor reductive work-up—it is followed only by hydrolysis. Carbon dioxide is obtained from the CH group of a terminal alkyne. 

Carboxylic acids are produced when alkynes are subjected to ozonolysis... 

Ozonolysis is sometimes used as a tool m structure determination By identifying the carboxylic acids produced we can deduce the structure of the alkyne As with many... 

Carbon-carbon triple bonds can be cleaved by ozonolysis The cleavage products are carboxylic acids... 

A certain carboxylic acid (C14H26O2) which can be isolated from whale blubber or sardine oil yields nonanal and 0=CH(CH2)3C02H on ozonolysis What is the structure of this acid" ... 

Hydrolysis of cinenn I gives an optically active carboxylic acid (+) chrysanthemic acid Ozonolysis of (+) chrysanthemic acid followed by oxidation gives acetone and an optically active dicarboxyhc acid (—) caronic acid (C7H10O4) What is the struc ture of (—) caronic acid" Are the two carboxyl groups cis or trans to each other What does this information tell you about the structure of (+) chrysanthemic acid" ... 

Rhodium catalyst is used to convert linear alpha-olefins to heptanoic and pelargonic acids (see Carboxylic acids, manufacture). These acids can also be made from the ozonolysis of oleic acid, as done by the Henkel Corp. Emery Group, or by steam cracking methyl ricinoleate, a by-product of the manufacture of nylon-11, an Atochem process in France (4). Neoacids are derived from isobutylene and nonene (4) (see Carboxylic acids, trialkylacetic acids). 

The ester, formed from the acid (COCE, toluene then CH2=CHCH2CH20H, acetone, —78° warm to rt, 70-94% yield), can be cleaved by ozonolysis followed by Et3N or DBU treatment (79-99% yield), the ester is suitable for the protection of enolizable and base-sensitive carboxylic acids. ... 

Alkenes are cleaved to carbonyl compounds by ozonolysis. This reaction is useful both for synthesis (preparation of aldehydes, ketones, or carboxylic acids) and analysis. When applied to analysis, the carbonyl compounds are isolated and identified, allowing the substituents attached to the double bond to be deduced. 

Ozonolysis of 5,8,9-trihydroxy-2,3-dihydro-l//-pyrimido[l, 2-n]quinoline-3-carboxylic acid (420), obtained from isopyoverdin isolated from Pseudomonas putida BTPl by acidic hydrolysis, gave l-2,4-diaminobutyric acid, which confirmed the hypothesis that heterocyclic chromophores 1 and 4 of pyoverdin and isopyoverdin, respectively, could have the same precursor, and the configuration at C(3) should be 5 (97ZN(C)549). 

Compound A, C/H, was found to be optically active. On catalytic reductior over a palladium catalyst, 2 equivalents of hydrogen were absorbed, yielding compound B, CyH. On ozonolysis of A, two fragments were obtained. One fragment was identified as acetic acid. The other fragment, compound C, wa an optically active carboxylic acid, C5Hl002- Write the reactions, and drav structures for A. B and C. 

Ebdon and coworkers22 "232 have reported telechelic synthesis by a process that involves copolymerizing butadiene or acetylene derivatives to form polymers with internal unsaturation. Ozonolysis of these polymers yields di-end functional polymers. The a,o>dicarboxy1ic acid telechelic was prepared from poly(S-s tot-B) (Scheme 7.19). Precautions were necessary to stop degradation of the PS chains during ozonolysis. 28 The presence of pendant carboxylic acid groups, formed by ozonolysis of 1,2-diene units, was not reported. 

Hydroxy-5-oxo-3,5-seco-4-norandrostane-3-carboxylic acid has been prepared by ozonolysis of testosterone2-4 or of testosterone acetate, followed by alkaline hydrolysis,5 and by the oxidation of testosterone acetate with ruthenium tetroxide.9... 

The zwitterion (59) is thereby prevented from reacting with the ketone (58) to form the ozonide in the normal way, and both (58) and (60) may now be isolated and identified. In preparative ozonolysis it is important to decompose the ozonide (57a) by a suitable reductive process, as otherwise H202 is produced (on decomposition of the ozonide with H20, for example) which can further oxidise sensitive carbonyl compounds, e.g. aldehydes— carboxylic acids. 

Unsaturated acids may be split chemically at their double bonds. Permanganate-periodate oxidation has been used to produce the corresponding carboxylic acids, while an alternative technique of ozonolysis results in the formation of aldehydes and aldehyde esters. All these reaction products may be identified by GLC and the information used to determine the position of the double bond in the original fatty acid. 

The formation of 1,2,3-trioxolanes from an alkene and ozone is the first step in the ozonolysis reaction, which is widely used in synthesis to convert alkenes to aldehydes or carboxylic acids. No instances of double bond migration during ozonolysis are known (since the first step is a cyclo-... 

Reaction of 3,5-disubstituted-1,2,4-trioxolanes (89) with oxidants (usually under basic conditions) leads to carboxylic acids (Equation (14)). This reaction is often carried out as the work up procedure for alkene ozonolysis, avoiding the need to isolate the intermediate ozonide. Typical oxidants are basic hydrogen peroxide or peracids and this type of oxidative decomposition is useful for both synthetic and degradative studies. 

Trioxolanes are key intermediates in the ozonolysis of alkenes (Section 4.16.8.2). This reaction is of considerable importance in synthetic chemistry where ozonide intermediates are often reduced (to aldehydes or alcohols) or oxidized (to carboxylic acids) in situ. Advantage has been taken of the stability of certain derivatives to investigate selective chemical reactions. An example of selective reduction is shown in Scheme 47 <91TL6454> with other uses of the 1,2,4-trioxolane ring as a masked aldehyde or ester referred to in Section 4.16.5.2.1. 

The viabihty of this synthetic approach to the introduction of a carboxylic acid fimction at C2 has been demonstrated in two ways. Following lithium diphenylcuprate addition to 564, the newly introduced phenyl group is subsequently degraded by ozonolysis to provide 567. Alternatively, reaction of 564 with diethylaluminium cyanide in toluene gives 568 which is also conveniently transformed into 567... 

Synthetic operations involving ozonolysis lead to formation of aldehydes, ketones or carboxylic acids, as shown in Scheme 16, or to various peroxide compounds, as depicted in Scheme 7 (Section V.B.5), depending on the nature of the R to R substituents and the prevalent conditions of reaction no effort is usually made to isolate either type of ozonide, but only the final products. This notwithstanding, intermediates 276 and 278 are prone to qualitative, quantitative and structural analysis. The appearance of a red-brown discoloration during ozonization of an olefin below — 180°C was postulated as due to formation of an olefin-ozone complex, in analogy to the jr-complexes formed with aromatic compounds however, this contention was contested (see also Section V1I.C.2). 

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