* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Download Chapter 1 Structure and Bonding
George S. Hammond wikipedia , lookup
Ring-closing metathesis wikipedia , lookup
Asymmetric induction wikipedia , lookup
Kinetic resolution wikipedia , lookup
Ene reaction wikipedia , lookup
Hydroformylation wikipedia , lookup
Bottromycin wikipedia , lookup
Wolff rearrangement wikipedia , lookup
Strychnine total synthesis wikipedia , lookup
Ch. 19-20 Lect. 2 Carboxylic Acids and Derivatives I. Alkanoyl Halides A. Preparation 1) Inorganic esters utilized, just as in conversion of alcohols to alkyl halides 2) PBr3, SOCl2 convert carboxylic acids to alkanoyl halides O R SOCl2 -HCl OH O R R H R OSOCl O H Cl OH R OSOCl OSOCl Cl H O O O S Cl Cl B. + + O R Cl + O S O Nomenclature 1) Pentanoic acid becomes pentanoyl chloride 2) + H+Cl- O CH3CH2CH2CH2 Cyclohexane carboxylic acid becomes cyclohexanecarbonyl chloride O Cl Cl C. Reactivity: most reactive and useful derivative 1. Modified LiAlH4 reagent LiAl[OC(CH3)3]3H required to prevent over-reduction to alcohols 2. Organocuprates are less reactive alkyl metal reagents to prevent second addition to ketone 3. 4. 5. 6. Amines do addition-elimination to give amides Alcohols do addition-elimination to give esters Acids do addition-elimination to give anhydrides Water does addition-elimination to give acids II. Anhydrides A. Preparation 1) As just seen, the reaction of an acid and an alkanoyl halide form anhydrides 2) The –OH group of the acid is a weak nucleophile for the reactive alkanoyl halide 3) Dehydration of two carboxylic acids can also work if 5-6 membered ring forms O O R O OH R O Cl R COOH O O R COOH -H2O O O B. Nomenclature 1) Replace “acid” with “anhydride” for the components 2) Acetic anhydride; Butanedioc anhydride 3) Unsymmetric anhydrides or mixed anhydrides are possible O O O O Acetic propanoic anhydride Acetic anhydride H3C O CH2CH3 H3C O CH3 C. Reactivity 1) All the alkanoyl halides reactions work for anhydrides, but are slower 2) Leaving group is a carboxylate anion, removed by aqueous extraction 3) Use anhydride as an activated substitute for reactions with carboxylic acids III. Esters A. Preparation 1) As seen, alcohols do addition-elimination to alkanoyl halides to give esters 2) Acid catalyzed addition-elimination of alcohols to carboxylic acids is also useful 3) Esterification (and Ester Hydrolysis) Mechanism O H R OH O + H O + R R O H3C + H O + R O O H CH3 O CH3O H OH H R H O O R OH + H O + R H O H CH3 H H O H O H O HOCH3 R O CH3 O CH3 CH3 4) Intramolecular esterifications give cyclic esters called lactones O HO H2SO4, H2O COOH -H2O O Favored for 5-6 membered rings B. NH2 O O 2-methylpropyl propanoate 3-methylbutyl pentanoate methyl 2-aminobenzoate Reactivity 1. Ester hydrolysis forms the component alcohol and carboxylic acid a. Acid catalyzed reaction is the reverse of esterification shown above b. Base catalyzed ester hydrolysis is also possible O R OMe O O C. O Nomenclature: named as alkyl alkanoates -OH O R O CH3 2. R O -OCH3 O CH3 R O -OCH3 O H OH R H+, H2O O Transesterification occurs with alcohols a. Acid or base catalyzed conversion of one ester to another b. Control the equilibrium by adding a large excess of the new alcohol O O CH3CH2OH O CH3 + H or -OCH2CH3 R O CH2CH3 3. Ester + Amine + Heat gives Amides (amines are more nucleophilic than alcohols) O R O O CH3 + CH3NH2 R N CH3 H 4. Grignard Reagents + Esters give Alcohols a. The first reaction is an addition-elimination giving a Ketone product b. The Ketone reacts with another Grignard molecule giving the alcohol O O OH RMgBr H3C O CH3 5. O R H3C R RMgBr H3C R R Esters can be reduced by hydrides to alcohols or aldehydes a. LiAlH4 fully reduced the ester to an alcohol (similar to Grignard above) b. DIBAL reduces ester only to an aldehyde H O Al R O CH3 DIBAL = diisobutylaluminum hydride H D. Esters in Nature 1. Esters are important aroma and flavor agents in natural foods O a. Isopentyl acetate = banana oil H3C O b. Octyl acetate = orange oil c. Methyl salicylate = oil of wintergreen O H3C O O O OH 2. Waxes are long chain esters O a. Beeswax CH3(CH2)24 b. O (CH2)29CH3 Spermaciti: sperm whale wax CH3(CH2)14 3. Fats and Oils = triesters of glycerol (1,2,3-propanetriol) H2C O CH2OH CHOH O RCOOH HC O CH2OH Glycerol O O C O H2 O Saturated Fat or Oil O (CH2)15CH3 IV. Amides A. Preparation 1) Amines react with carboxylic acids as bases and as nucleophiles O O :NH3 Kinetic product R O H R O NH4+ 2) Heating favors the thermodynamic product: amide O R 3) O H R Amino acids cyclize to give lactams H3N+ B. O :NH3 Thermodynamic product NH2 O heat, -H2O NH COO- Nomenclature: alkanamides or cycloalkanecarboxamides Br O N H3C O NH2 NHCH3 N-methylacetamide O 4-bromo-N-ethyl-N-methylpentanamide cyclohexanecarboxamide C. Reactivity: least reactive of the carboxylic acid derivatives 1. Resonance structures prevent rotation around C—N bond a. Ea = 21 kcal/mol for rotation about this single bond b. Two peaks seen in the proton NMR O H3C O .. N CH3 H3C CH3 CH3 2. + CH 3 N Hydrolysis requires heat and concentrated acid or base a. Proteins are held together by strong amide bonds; they don’t break easily O H3C O + N H or -OH CH3 OH2 H3C OH CH3 3. Al O H3C Reduction to Amine by LiAlH4 N CH3 CH3 LiAlH4 H O R .. CH3 R N H CH3 H CH3 N+ CH3 Iminium ion H H R CH3 N H CH3 V. Alkanenitriles A. Preparation: SN1 or SN2 reaction of haloalkanes 2 Br B. N 1 3 1 4 2 -CN 3 N Nomenclature 1) Alkanenitriles or cycloalkanenitriles N butanenitrile C. Reactivity: synthesis of carboxylic acids 1) Acid catalyzed mechanism NH R H N R H R 2) 3) 4) R N H + NH2 NH2+ + OH NH + + R cyclohexanecarbonitrile OH R OH + OH2 N H R NH2 -H+ R O + H -H+ OH2+ OH2 amide hydrolysis Similar Base catalyzed mechanism Adds one carbon to the haloalkane, then turns it into carboxylic acid Make derivatives from there; take advantage of all of their reactions RCOOH