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19-1 Naming the Carb oxvlic Acids CHAPTER 19 Carboxylic Acids 2 d acids. d cyclic acids are n omatic acids are named benzoic acids. B2weec 19-2nd Pysic Poei of arboic nctiononand ormhyo vlcadstobutd are comleteyublen neegea8o8amegg-8keao92cartootcacd Carbavylic Acids Form Dimers Readily a0一R--8 1
1 CHAPTER 19 Carboxylic Acids 19-1 Naming the Carboxylic Acids Chemical Abstracts retains the common names for the two simplest carboxylic acids, formic acid and acetic acid. The IUPAC system derives the name of carboxylic acids by replacing the ending –e in the parent alkane by the ending –oic acid. The carbonyl group and the functional groups of its derivatives take precedence in naming over any other groups discussed so far: The alkanoic acid stem is numbered by assigning 1 to the carbonyl carbon and labeling any substituents along the longest chain incorporating the CO2H group accordingly. When other functional groups are present, the main chain is chosen to include other functional groups as much as possible. Saturated cyclic acids are named as cycloalkanecarboxylic acids. Aromatic acids are named benzoic acids. Dicarboxylic acids are referred to as dioic acids. Structural and Physical Properties of Carboxylic Acids 19-2 Formic acid is planar. The molecular structure of formic acid is roughly planar, which is characteristic of carboxylic acids in general. The carboxy group is polar and forms hydrogenbonded dimers. The carboxy function is strongly polar and forms hydrogen bonds to other polarized molecules such as water, alcohols and other carboxylic acids. Carboxylic acids up to butanoic acid are completely soluble in water. As neat liquids, and even in fairly dilute solutions, carboxylic acids form hydrogen-bonded dimers (6–8 kcal mol-1)
19-3 NMR and IR Spectroscopy of Carboxylic Acids 子密 CH.CH.CH.CH.COH 2H 2H The carboxy group shows two important IR bands. ic acids show thre mode n several ways,whic -- 2
2 Carboxylic acids have relatively high melting and boiling points due to hydrogen bonding in both the solid and liquid states. Volatile carboxylic acids (low MW) exhibit characteristically strong odors (butanoic acid, cheese; (E)-3-methyl-2-hexenoic acid, human sweat). 19-3 NMR and IR Spectroscopy of Carboxylic Acids The carboxy hydrogen and carbon are deshielded. Hydrogens on a carbon next to a carbonyl group are slightly deshielded. The effect diminishes rapidly with increasing distance from the carbonyl. The hydroxyl proton resonates at very low field (δ = 10-13 ppm). Its chemical shift varies strongly with concentration, solvent and temperature because of its involvement in hydrogen bonding. The 13C NMR chemical shifts of carboxylic acids are similar to those of aldehydes and ketones. The amount of deshielding is smaller because of the presence of the extra OH group. The smaller deshielding can be attributed to the extra resonance form present in carboxylic acids: The carboxy group shows two important IR bands. Stretching frequencies for both the carbonyl group and the hydroxy substituent are seen in the IR spectra of carboxy groups. The O-H bond exhibits a very broad band at 2500–3300 cm-1, lower than for alcohols because of strong hydrogen bonding. Mass spectra of carboxylic acids show three modes of fragmentation. Fragmentation of carboxylic acids occurs in several ways, which results in a fairly weak molecular ion peak
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3 19-4 Acidic and Basic Character of Carboxylic Acids Carboxylic acids are relatively strong acids. Carboxylic acids have much lower pKa values than do alcohols. The lowered pKa values are due to the electron-withdrawing effect of the positively polarized carbonyl carbon and the resonance stabilization of the carboxylate group. Two of the three resonance forms of the carboxylate ion are equivalent, leading to a symmetrical ion with equal carbonoxygen bond lengths (1.26 Å), midway between a carbon-oxygen double bond (1.20 Å) and a carbon-oxygen single bond (1.34 Å). Electron-withdrawing substituents increase the acidity of carboxylic acids. The inductive effect of electron-withdrawing groups close to the carboxy group causes an increase in acidity. Three electron-withdrawing groups on the α-carbon sometimes results in acidity near that of some inorganic acids. The dioic acids have two pKa values. In ethanedioic and propanedioic acids, the first pKa is lowered by the electron-withdrawing effect of the second. In higher dioic acids, both pKa values are close to monocarboxylic acids. Carboxylate salts of carboxylic acids can be prepared by treatment of the acid with a base, such as NaOH, Na2CO3 or NaHCO3. These salts are much more water soluble than the corresponding acids. Carboxylate salts are named by specifying the metal and then replacing “ic acid” with “ate”. Carboxylic acids may be protonated on the carbonyl oxygen. The carbonyl oxygen of a carboxylic acid may be protonated by strong acids to give alkyloxonium ions. The carbonyl oxygen is more basic than the –OH group of alcohols due to resonance stabilization of the alkyloxonium ion. Note that the protonation reaction is not particularly strong. 19-5 Carboxylic Acid Synthesis in Industry Formic acid and acetic acid are manufactured on a large scale industrially
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4 Other important industrial carboxylic acids include the two dicarboxylic acids: •Hexanedioic acid Nylon •1,4-benzenedicarboxylic acid Plastics Methods for Introducing the Carboxy Functional Group 19-6 Oxidation of primary alcohols and of aldehydes furnishes carboxylic acids. Primary alcohols oxidize first to aldehydes, which then may further oxidize to carboxylic acids. Oxidants include CrO2, KMnO4 and HNO3. Nitric acid is often chosen as the oxidant because it is one of the cheapest strong oxidants. Organometallic reagents react with carbon dioxide to give carboxylic acids. Carbonation, or reaction of an organometallic reagent with CO2 (dry ice), produces a carboxylate salt, which yields a carboxylic acid upon protonation in aqueous acid. A two step synthesis allows the conversion of an alkyl halide into the corresponding carboxylic acid having one more carbon. Nitriles hydrolyze to carboxylic acids. A second method for preparing a carboxylic acid with an additional carbon is through the synthesis and hydrolysis of a nitrile, RC≡N. Nitrile hydrolysis is preferable to Grignard carbonation when the substrate contains other functional groups capable of reacting with the Grignard reagent (hydroxy, carbonyl, nitro). Substitution at the Carboxy Carbon: the Addition-Elimination Mechanism 19-7 The carbonyl carbon is attacked by nucleophiles. Carboxylic acids and their derivatives of the form RCOL (L = leaving group) can be attacked by nucleophiles. Unlike the reactions with aldehydes and ketones, the attacking nucleophile displaces the leaving group resulting in an additionelimination reaction. An addition-elimination reaction proceeds through a tetrahedral intermediate
Addition-climination is catalyzed by acid or base. Base catalysisproceeds bydeptn the nuceophlle. sP上A年0mnae oggacn2c5am 2的 A8atemewna5eaesCiodmgtoaceophesarebase Compeding React of aCAcdhN 0: 19-Carbry Dertvatives:Alkanoy (A) bagam-8eWatuear6ew8e8gagng dingP6a8H58e。2re8euahomcartoqyi 5
5 Addition-elimination is catalyzed by acid or base. Acid catalysis of an addition-elimination reaction proceeds by initial protonation of the carbonyl group and subsequent protonation of the leaving group. Base catalysis proceeds by deprotonating the nucleophile. Substitution in carboxylic acids is inhibited by a poor leaving group and the acidic proton. Two problems can be encountered when trying to convert a carboxylic acid into one of its derivatives by the additionelimination process. •Hydroxide ion is a poor leaving group. •Carboxylic proton is acidic and most nucleophiles are bases. An alternate acid-base reaction may occur. With less basic nucleophiles, especially under acidic conditions, substitution through the addition-elimination mechanism may occur. In the esterification of a carboxylic acid, an alcohol and a carboxylic acid react in the presence of acid to form an ester and water. The acid serves to protonate both the carbonyl oxygen, activating the carbonyl towards nucleophilic addition, and the carboxy OH, converting it into a better leaving group. Carboxylic Acid Derivatives: Alkanoyl (Acyl) Halides 19-8 Alkanoyl (acyl) halides are formed by using inorganic derivatives of carboxylic acids. Alkanoyl (acyl) halides can be prepared from carboxylic acids by using reagents such as SOCl2 or PBr3. The reaction with either reagent begins with the conversion of the poor leaving group, -OH, into a good leaving group
