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Transcript
Ch 17- Carboxylic Acids and their derivatives Introduction • The Carboxyl group • One of the most widely occurring groups in chemistry and biochemistry • It is the parent group of a large family of related compounds called acyl compounds or carboxylic acid derivatives • Examples Nomenclature • Carboxylic Acids • IUPAC nomenclature – Drop –e – Add –oic acid • The carboxyl carbon is assigned #1 • Examples • Common Names: Esters • To name an ester, you name the group attached to the oxygen as an alkyl group first then name the rest as the acid, dropping the – ic acid and adding –ate • Examples Nomenclature • Carboxylic Anhydrides • IUPAC – Drop the acid from the name of the carboxylic acid and then add the word anhydride Nomenclature • Acyl Chlorides • IUPAC – Drop the –ic acid, then add –yl chloride Nomenclature • Amides • IUPAC – Drop the –ic acid, then add –amide – Alkyl groups on the nitrogen atom of amides are named as substituents, and N- is used as the locant. Nomenclature • Nitriles • IUPAC – Acyclic nitriles are named by adding the suffix –nitrile to the name of the corresponding hydrocarbon. – The Carbon of the nitrile is assigned the #1 Properties • Polar • Carboxylic Acid can form strong hydrogen bonds • Results in high boiling points • Appreciable water solubility Synthesis of Carboxylic Acids • 1) oxidation of Alkenes • 2) oxidation of Aldehydes and primary alcohols • 3) Oxidation of alkyl benzenes • 4) Oxidation of a benzene ring Synthesis of Carboxylic Acids • 5) Oxidation of methyl ketones (haloform reaction) • 6) Hydrolysis of cyanohydrins and other nitriles • 7) Carbonation of Grignard reagents Reactions of Carboxylic Acids • 1) Nucleophilic Addition- Elimination at the Acyl Carbon – In the past, we have seen the nucleophilic addition to the carbonyl carbon – When the carbon is a carboxyl carbon, one of a carboxylic acid or a derivative, the addition is followed by an elimination and the return of the carbonyl group Reactions of Carboxylic Acids • These two reactions have the same initial step • The initial step involves nucleophilic addition at the carbonyl carbon • With both groups of compounds, this initial attack is facilitated by the same factors: – The relative steric openness of the carbonyl carbon atom – The ability of the carbonyl oxygen atom to accommodate an electron pair of the C-O double bond Reactions of Carboxylic Acids • After that initial step, the reactions differ. • The aldehyde/ketone usually accept a proton to form a stable addition product • In contrast, the acyl compound usually eliminates a leaving group to regenerate the Carbon-Oxygen double bond • This leads to a substitution product instead of an addition product Reactions of Carboxylic Acids • Acyl compounds react as they do because they all have good, or reasonably good, leaving groups attached to the carbonyl carbon • An acid chloride, for example, can eliminate a chloride ion which is a very weak, stable base, thus a good leaving group. • Examples: Reactions of Carboxylic Acids • Aldehydes and ketones do not perform this elimination because they would have to eliminate a hydride (H-) or alkanide (R-) species. • Both are very reactive and not good leaving groups Order of Reactivity of Acyl Compounds • Series: • In general, the carboxylic acid derivatives can be synthesized from one another through this addition-elimination reaction • However, we must keep in mind the reactivity series • Less reactive acyl compounds can be synthesized from more reactive ones, but the reverse is usually very difficult and requires special reagents • Examples: Synthesis of Esters • Fisher Esterifications- an acid-catalyzed condensation reaction between an alcohol and a carboxylic acid • Examples: • Mechanism: • Note: Oxygen in ester comes from alcohol Reactions of Esters • Base Promoted Hydrolysis of Esters: Saponification • Esters are made by acid-catalyzed hydrolysis of Carboxylic acids • They can be converted back to the carboxylic acid through a base catalyzed mechanism called saponification • Example: • Mechanism: Lactones • Lactones- a cyclic ester • They can be made from carboxylic acids with a hydroxyl group at the gamma or delta position • The reaction is acid catalyzed: • Lactones are hydrolyzed in aqueous base just like other esters back to the carboxylic acid Decarboxylations of Carboxylic Acids • Decarboxylation- a reaction in which a carboxylic acid loses CO2 • Example: • These reactions are not easy to perform and usually require special groups to be present to occur • One example is carboxylic acid with a ketone at the beta position Decarboxylations of Carboxylic Acids • There are two reasons for the ease of this reaction: – 1) The reaction can proceed through a six membered cyclic transition state to form an enol which tautomerises to the ketone – 2) When the carboxylate anion decarboxylates, it forms a resonance-stabilized enolate anion
