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Reactions of aldehydes and ketones : oxidation reduction nucleophilic addition

Reactions of aldehydes and ketones : oxidation reduction nucleophilic addition Aldehydes are easily oxidized, ketones are not. Aldehydes are more reactive in nucleophilic additions than ketones. alkane. alcohol. reduction. reduction. aldehyde ketone. addition product. nucleophilic

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Reactions of aldehydes and ketones : oxidation reduction nucleophilic addition

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  1. Reactions of aldehydes and ketones: • oxidation • reduction • nucleophilic addition • Aldehydes are easily oxidized, ketones are not. • Aldehydes are more reactive in nucleophilic additions than ketones.

  2. alkane alcohol reduction reduction aldehyde ketone addition product nucleophilic addition oxidation carboxylic acid

  3. nucleophilic addition to carbonyl:

  4. Mechanism:nucleophilic addition to carbonyl 1) 2)

  5. Mechanism:nucleophilic addition to carbonyl,acid catalyzed 1) 2) 3)

  6. Aldehydes & ketones, reactions: • Oxidation • Reduction • Addition of cyanide • Addition of derivatives of ammonia • Addition of alcohols • Cannizzaro reaction • Addition of Grignard reagents • 8) (Alpha-halogenation of ketones) • 9) (Addition of carbanions)

  7. 1) Oxidation • Aldehydes(very easily oxidized!) • CH3CH2CH2CH=O + KMnO4, etc.  CH3CH2CH2COOH • carboxylic acid • CH3CH2CH2CH=O + Ag+ CH3CH2CH2COO- + Ag • Tollen’s test for easily oxidized compounds like aldehydes. • (AgNO3, NH4OH(aq)) Silver mirror

  8. Ketones only oxidize under vigorous conditions via the enol.

  9. b) Methyl ketones: Yellow ppt test for methyl ketones

  10. 2) Reduction: • To alcohols

  11. Then + H+ alcohol

  12. Reduction b) To hydrocarbons

  13. 3) Addition of cyanide

  14. 1) 2)

  15. Cyanohydrins have two functional groups plus one additional carbon. Nitriles can be hydrolyzed to carboxylic acids in acid or base:

  16. 4) Addition of derivatives of ammonia

  17. 1) 2) 3)

  18. melting points of derivatives ketones bpsemi- 2,4-dinitro- oxime carbazone phenylhydrazone 2-nonanone 195 119 56 acetophenone 202 199 240 60 menthone 209 189 146 59 2-methylacetophenone 214 205 159 61 1-phenyl-2-propanone 216 200 156 70 propiophenone 220 174 191 54 3-methylacetophenone 220 198 207 55 isobutyrophenone 222 181 163 94

  19. 5) Addition of alcohols

  20. Cannizzaro reaction. (self oxidation/reduction) • a reaction ofaldehydes without α-hydrogens

  21. Formaldehyde is the most easily oxidized aldehyde. When mixed with another aldehyde that doesn’t have any alpha-hydrogens and conc. NaOH, all of the formaldehyde is oxidized and all of the other aldehyde is reduced. Crossed Cannizzaro:

  22. 7) Addition of Grignard reagents.

  23. 1) 2)

  24. #3 synthesis of alcohols. Used to build larger molecules from smaller organic compounds.

  25. Aldehydes & ketones, reactions: • Oxidation • Reduction • Addition of cyanide • Addition of derivatives of ammonia • Addition of alcohols • Cannizzaro reaction • Addition of Grignard reagents • 8) (Alpha-halogenation of ketones) • 9) (Addition of carbanions)

  26. Planning a Grignard synthesis of an alcohol: • The alcohol carbon comes from the carbonyl compound. • The new carbon-carbon bond is to the alcohol carbon. New carbon-carbon bond

  27. “The Grignard Song” (sung to the tune of “America the Beautiful”) Harry Wasserman The carbonyl is polarized, the carbon end is plus. A nucleophile will thus attack the carbon nucleus. The Grignard yields an alcohol of types there are but three. It makes a bond that corresponds from “C” to shining “C.”

  28. or

  29. HX Mg ROH RX RMgX larger alcohol H2O ox. R´OH -C=O

  30. Stockroom: alcohols of four-carbons or less: (methanol, ethanol, 1-propanol, 2-propanol, 1-butanol, 2-butanol, 2-methyl-2-propanol, 2-methyl-1-propanol.) benzene cyclohexanol any needed inorganic reagents or solvents.

  31. Grignard synthesis of 4-methyl-2-pentanol from alcohols of four-carbons or less: Step one: determine the carbonyl compound and Grignard reagent that you would use: H2O CH3 CH3CHCH2MgBr + CH3CH=O CH3 CH3CHCH2CHCH3 OH Step two: show the syntheses of the Grignard reagent and the carbonyl compound from alcohols…

  32. CH3 PBr3 CH3 Mg CH3 CH3CHCH2OH CH3CHCH2Br CH3CHCH2MgBr H+ K2Cr2O7 CH3 CH3CH2OH CH3CH=O CH3CHCH2CHCH3 special cond. OH 4-methyl-2-pentanol

  33. 2-phenyl-2-propanol

  34. 1-methylcyclohexanol

  35. cyclohexylmethanol

  36. ketone aldehyde RCOOH ROH ROR alkene RX Alcohols are central to organic syntheses RH alkyne

  37. HX Mg ROH RX RMgX larger alcohol H2O ox. R´OH -C=O

  38. Using the Grignard synthesis of alcohols we can make any alcohol that we need from a few simple alcohols. From those alcohols we can synthesize alkanes, alkenes, alkynes, alkyl halides, ethers, aldehydes, ketones, carboxylic acids… eg. Outline all steps in a possible laboratory synthesis of 3-methyl-1-butene from alcohols of four carbons or less. CH3 CH3CHCH=CH2

  39. Retrosynthesis: alkenes, syntheses: 1. Dehydrohalogenation of an alkyl halide 2. Dehydration of an alcohol 3. Dehalogenation of a vicinal dihalide 4. Reduction of an alkyne Methods 3 & 4 start with compounds that are in turn made from alkenes.

  40. Dehydration of an alcohol? CH3 H+ CH3CHCHCH3 yields a mixture of alkenes OH CH3 H+ CH3CHCH2CH2-OH yields a mixture of alkenes E1 mechanism via carbocation!

  41. Dehydrohalogenation of an alkyl halide? CH3 KOH(alc) CH3CHCHCH3 yields a mixture of alkenes Br CH3 KOH(alc) CH3 CH3CHCH2CH2-Br CH3CHCH=CH2 only product  E2 mechanism, no carbocation, no rearrangement

  42. CH3 PBr3 CH3 CH3CHCH2CH2-OH CH3CHCH2CH2-Br 1o alcohol, SN2 mechanism, no rearrangement! CH3 KOH(alc) CH3 CH3CHCH2CH2-Br CH3CHCH=CH2 Use the Grignard synthesis to synthesize the intermediate alcohol from the starting materials.

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