Aldehydes, halogenation mechanism

Chemical Properties. A combination of excellent chemical and mechanical properties at elevated temperatures result in high performance service in the chemical processing industry. Teflon PEA resins have been exposed to a variety of organic and inorganic compounds commonly encountered in chemical service (26). They are not attacked by inorganic acids, bases, halogens, metal salt solutions, organic acids, and anhydrides. Aromatic and ahphatic hydrocarbons, alcohols, aldehydes, ketones, ethers, amines, esters, chlorinated compounds, and other polymer solvents have Httle effect. However, like other perfluorinated polymers,they react with alkah metals and elemental fluorine. 

Reactions 11-22-11-26 involve the introduction of a CH2Z group, where Z is halogen, hydroxyl, amino, or alkylthio. They are all FriedeI-Crafts reactions of aldehydes and ketones and, with respect to the carbonyl compound, additions to the C=0 double bond. They follow mechanisms discussed in Chapter 16. 

It is not the aldehyde or ketone itself that is halogenated, but the corresponding enol or enolate ion. The purpose of the catalyst is to provide a small amount of enol or enolate. The reaction is often done without addition of acid or base, but traces of acid or base are always present, and these are enough to catalyze formation of the enol or enolate. With acid catalysis the mechanism is... 

Aldehydes can be directly converted to acyl chlorides by treatment with chlorine however, the reaction operates only when the aldehyde does not contain an a hydrogen and even then it is not very useful. When there is an a hydrogen, a halogenation (12-4) occurs instead. Other sources of chlorine have also been used, among them S02Cl2 and r-BuOCl. The mechanisms are probably of the free-radical type. V-Bromosuccinimide, with AIBN (p. 912) as a catalyst, has been used to convert aldehydes to acyl bromides. 

Ethanol is both an inducer and substrate of CYP2E1. Indeed, CYP2E1 seems to be structurally geared to favor small volatile molecules such as ketones, aldehydes, alcohols, halogenated alkenes, and alkanes as substrates (36). Moreover, many of these same compounds, like ethanol, are inducers of the enzyme. A major mechanism by which this diverse group of compounds appears to initiate induction is by inhibiting normal enzyme degradation. 

Disinfectants come from various chemical classes, including oxidants, halogens or halogen-releasing agents, alcohols, aldehydes, organic acids, phenols, cationic surfactants (detergents) and formerly also heavy metals. The basic mechanisms of action involve de-naturation of proteins, inhibition of enzymes, or a dehydration. Effects are dependent on concentration and contact time. 

Mechanism 22-6 Base-Promoted Halogenation 1054 Mechanism 22-7 Final Steps of the Haloform Reaction 1056 Mechanism 22-8 Acid-Catalyzed Alpha Halogenation 1058 22-6 Alpha Bromination of Acids The HVZ Reaction 1059 22-7 The Aldol Condensation of Ketones and Aldehydes 1060... 

A final piece of evidence comes from deuterium-exchange expariments. If an aldehyde or ketone ts created with U 0 instead cf H 0", the acidic A hydrogens are replaced by deuterium. For a given ketone, the rate of deuterium exchange is identical to the rate of halogenation. indicating that the same intermediate is involved in both procesaes. That common intermediate can -only bo an enol (see the reaction mechanism at the top of p. 909). 

Iodine accelerates the decomposition of acetaldehyde In the steady-state range, the order is approximately 1.0 and 0.5 in aldehyde and iodine, respectively. The experimental results of Rollefson and Faull have been reinterpreted and added to by O Neal and Benson . The iodine-catalysed reaction is a free radical chain process initiated by the attack of an iodine atom on the acetaldehyde molecule. The proposed mechanism fits the experimental data very well. The thermal decomposition of acetaldehyde is catalysed also by other halogens and halogen compounds . 

With respect to the enol, this mechanism is similar to that of halogenation (12-4). A side reaction that is sometimes troublesome is further condensation, since the product of an aldol reaction is still an aldehyde or ketone. The aldol condensation of aldehydes has also been done using a mixture of pyrrolidine and benzoic acid. ... 

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