1 / 122

Chapter 17 Aldehydes and Ketones. Nucleophilic Addition to the Carbonyl Group

Chapter 17 Aldehydes and Ketones. Nucleophilic Addition to the Carbonyl Group. 17.1 Nomenclature. O. O. H. H. O. O. HCCHCH. IUPAC Nomenclature of Aldehydes. Base the name on the chain that contains the carbonyl group and replace the -e ending of the hydrocarbon by -al. O. O. H. H.

agalia
Download Presentation

Chapter 17 Aldehydes and Ketones. Nucleophilic Addition to the Carbonyl Group

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Chapter 17Aldehydes and Ketones.Nucleophilic Additionto theCarbonyl Group

  2. 17.1Nomenclature

  3. O O H H O O HCCHCH IUPAC Nomenclature of Aldehydes Base the name on the chain that contains the carbonyl group and replace the -e ending of the hydrocarbon by -al.

  4. O O H H O O HCCHCH IUPAC Nomenclature of Aldehydes 4,4-dimethylpentanal 5-hexenal 2-phenylpropanedial(keep the -e endingbefore -dial)

  5. O when named as a suffix C when named as a substituent H formyl group carbaldehyde orcarboxaldehyde IUPAC Nomenclature of Aldehydes

  6. O O CH3CH2CCH2CH2CH3 CH3CHCH2CCH3 CH3 H3C O Substitutive IUPAC Nomenclature of Ketones Base the name on the chain that contains the carbonyl group and replace -e by -one. Number the chain in the direction that gives the lowest number to the carbonyl carbon.

  7. O O CH3CH2CCH2CH2CH3 CH3CHCH2CCH3 CH3 H3C O Substitutive IUPAC Nomenclature of Ketones 3-hexanone 4-methyl-2-pentanone 4-methylcyclohexanone

  8. O O CH3CH2CCH2CH2CH3 CH2CCH2CH3 O H2C CH CHC CH2 Functional Class IUPAC Nomenclature of Ketones List the groups attached to the carbonyl separately in alphabetical order, and add the word ketone.

  9. O O CH3CH2CCH2CH2CH3 CH2CCH2CH3 O H2C CH CHC CH2 Functional Class IUPAC Nomenclature of Ketones ethylpropyl ketone benzylethyl ketone divinyl ketone

  10. 17.2Structure and Bonding:The Carbonyl Group

  11. Structure of Formaldehyde planar bond angles: close to 120° C=O bond distance: 122 pm

  12. very polar double bond dipole moment = 2.5D dipole moment = 0.3D The Carbonyl Group O 1-butene propanal

  13. O H O Carbonyl group of a ketone is morestable than that of an aldehyde Alkyl groups stabilize carbonyl groups the sameway they stabilize carbon-carbon double bonds,carbocations, and free radicals. heat of combustion 2475 kJ/mol 2442 kJ/mol

  14. O H O Spread is greater foraldehydes andketones than for alkenes Heats of combustion ofC4H8 isomeric alkenes CH3CH2CH=CH2 2717 kJ/mol cis-CH3CH=CHCH3 2710 kJ/mol trans-CH3CH=CHCH3 2707 kJ/mol (CH3)2C=CH2 2700 kJ/mol 2475 kJ/mol 2442 kJ/mol

  15. •• – •• O O •• •• •• C C + Resonance Description ofCarbonyl Group nucleophiles attack carbon; electrophiles attack oxygen

  16. Bonding in Formaldehyde Carbon and oxygen are sp2 hybridized

  17. Bonding in Formaldehyde The half-filledp orbitals oncarbon andoxygen overlapto form a  bond

  18. 17.3Physical Properties

  19. O OH Aldehydes and ketones have higher boilingthan alkenes, but lower boiling points than alcohols. boiling point More polar than alkenes, but cannot form intermolecular hydrogen bonds to other carbonyl groups –6°C 49°C 97°C

  20. 17.4Sources of Aldehydes and Ketones

  21. Many aldehydes and ketones occur naturally

  22. Table 17.1 Synthesis of Aldehydes and Ketones from alkenes ozonolysis from alkynes hydration (via enol) from arenes Friedel-Crafts acylation from alcohols oxidation A number of reactions alreadystudied provideefficient syntheticroutes to aldehydes and ketones.

  23. O O C C R H R OH 1. LiAlH4 PDC, CH2Cl2 2. H2O RCH2OH What about..? aldehydes from carboxylic acids

  24. O O COH CH 1. LiAlH4 PDCCH2Cl2 2. H2O CH2OH (83%) (81%) Example benzaldehyde from benzoic acid

  25. O O C C R R' R H 1. R'MgX OH PDC, CH2Cl2 2. H3O+ RCHR' What about..? ketones from aldehydes

  26. O CH3CH2C(CH2)3 CH3 1. CH3(CH2)3MgX H2CrO4 OH 2. H3O+ CH3CH2CH(CH2)3 CH3 Example 3-heptanone from propanal O C CH3CH2 H (57%)

  27. 17.5Reactions of Aldehydes and Ketones:A Review and a Preview

  28. Table 17.2 Reactions of Aldehydes and Ketones Already covered in earlier chapters: reduction of C=O to CH2 Clemmensen reduction Wolff-Kishner reduction reduction of C=O to CHOH addition of Grignard and organolithium reagents

  29. 17.6Principles of Nucleophilic Addition to Carbonyl Groups:Hydration of Aldehydes and Ketones

  30. O C •• •• •• •• HO O H C •• •• Hydration of Aldehydes and Ketones H2O

  31. OH O + C H2O R R' C R' R OH Substituent Effects on Hydration Equilibria compared to H electronic: alkyl groups stabilize reactants steric: alkyl groups crowd product

  32. Table 17.3 Equilibrium Constants and Relative Ratesof Hydration C=O hydrate K % Relative rate CH2=O CH2(OH)2 2300 >99.9 2200 CH3CH=O CH3CH(OH)2 1.0 50 1.0 (CH3)3CCH=O (CH3)3CCH(OH)2 0.2 17 0.09 (CH3)2C=O (CH3)2C(OH)2 0.0014 0.14 0.0018

  33. When does equilibrium favor hydrate? when carbonyl group is destabilized • alkyl groups stabilize C=O • electron-withdrawing groups destabilize C=O

  34. O Substituent Effects on Hydration Equilibria OH + C H2O R R C R R OH R = CH3: K = 0.000025 R = CF3: K = 22,000

  35. H – – •• •• HO O C O O C •• •• •• •• •• •• •• •• Mechanism of Hydration (base) Step 1: +

  36. •• •• HO O C •• •• •• H H O H •• – •• •• •• + HO OH C O •• •• •• •• •• Mechanism of Hydration (base) Step 2:

  37. H H O O C •• •• + •• H H + O + OH C •• •• •• H Mechanism of Hydration (acid) Step 1: +

  38. H H •• O OH C O •• •• •• + •• H H Mechanism of Hydration (acid) Step 2: + + OH C ••

  39. H H •• O H H + •• O •• H + H •• O OH C •• •• •• + •• O OH C •• H •• H Mechanism of Hydration (acid) Step 3:

  40. 17.7Cyanohydrin Formation

  41. •• N C C O O H C •• •• •• •• Cyanohydrin Formation + HCN

  42. C O N C •• •• •• •• Cyanohydrin Formation

  43. H – •• O H N C O C •• •• •• + •• H H •• O H N C O C •• •• •• •• H Cyanohydrin Formation

  44. Cl Cl O OH Cl Cl CH CHCN Example NaCN, water then H2SO4 2,4-Dichlorobenzaldehyde cyanohydrin (100%)

  45. OH O CH3CCH3 CH3CCH3 CN Example NaCN, water then H2SO4 (77-78%) Acetone cyanohydrin is used in the synthesis of methacrylonitrile (see problem 17.7).

  46. Amygdaline: vitamine B17

  47. 17.8Acetal Formation

  48. R O C •• •• R' HOH R •• •• HO O H C •• •• R' Recall Hydration of Aldehydes and Ketones

  49. R R •• •• R"O OR C •• O •• C •• •• R' R' R"OH R •• •• R"O O H C •• •• R' Alcohols Under Analogous Reactionwith Aldehydes and Ketones Product is called an acetal. ketalfrom ketone acetal from aldehyde ROH, H+ + H2O hemiacetal.

  50. H •• O O H C •• •• + R Mechanism of Acetal Formation First stage is analogous to hydration andleads to hemiacetal acid-catalyzed nucleophilic addition of alcohol to C=O H •• + O O C •• •• H R pKa = -7 pKa = - 2.5

More Related